Modified enzymes having polymer conjugates

ABSTRACT

The present invention relates to polypeptide-polymer conjugates having added and/or removed one or more attachment groups for coupling polymeric molecules on the surface of the polypeptide structure, a method for preparing polypeptide-polymer conjugates of the invention, the use of said conjugates for reducing the immunogenicity and allergenicity and compositions comprising said conjugate.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of application Ser. No. 09/024,532 filed on Feb. 17, 1998, now U.S. Pat. No. 6,245,901, which is a continuation of PCT/DK98/00046 filed on Feb. 6, 1998, and claims priority under 35 U.S.C. 119 of Danish application no. 0135/97 filed Feb. 6, 1997, the contents of which are fully incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to polypeptide-polymer conjugates having added and/or removed one or more attachment groups for coupling polymeric molecules on the surface of the 3D structure of the polypeptide, a method for preparing polypeptide-polymer conjugates of the invention, the use of said conjugated for reducing the immunogenicity and allergenicity, and compositions comprising said conjugate.

BACKGROUND OF THE INVENTION

The use of polypeptides, including enzymes, in the circulatory system to obtain a particular physiological effect is well-known in the medical arts. Further, within the arts of industrial applications, such as laundry washing, textile bleaching, person care, contact lens cleaning, food and feed preparation enzymes are used as a functional ingredient. One of the important differences between pharmaceutical and industrial application is that for the latter type of applications (i.e. industrial applications) the polypeptides (often enzymes) are not intended to enter into the circulatory system of the body.

Certain polypeptides and enzymes have an unsatisfactory stability and may under certain circumstances—dependent on the way of challenge—cause an immune response, typically an IgG and/or IgE response.

It is today generally recognized that the stability of polypeptides is improved and the immune response is reduced when polypeptides, such as enzymes, are coupled to polymeric molecules. It is believed that the reduced immune response is a result of the shielding of (the) epitope(s) on the surface of the polypeptide responsible for the immune response leading to antibody formation by the coupled polymeric molecules.

Techniques for conjugating polymeric molecules to polypeptides are well-known in the art.

One of the first commercially suitable techniques was described back in the early 1970's and disclosed in e.g. U.S. Pat. No. 4,179,337. Said patent concerns non-immunogenic polypeptides, such as enzymes and peptide hormones coupled to polyethylene glycol (PEG) or polypropylene glycol (PPG). At least 15% of polypeptides' physiological activity is maintained.

GB patent no. 1,183,257 (Crook et al.) describes chemistry for conjugation of enzymes to polysaccharides via a triazine ring.

Further, techniques for maintaining of the enzymatic activity of enzyme-polymer conjugates are also known in the art.

WO 93/15189 (Veronese et al.) concerns a method for maintaining the activity in polyethylene glycol-modified proteolytic enzymes by linking the proteolytic enzyme to a macromolecularized inhibitor. The conjugates are intended for medical applications.

It has been found that the attachment of polymeric molecules to a polypeptide often has the effect of reducing the activity of the polypeptide by interfering with the interaction between the polypeptide and its substrate. EP 183 503 (Beecham Group PLC) discloses a development of the above concept by providing conjugates comprising pharmaceutically useful proteins linked to at least one water-soluble polymer by means of a reversible linking group.

EP 471,125 (Kanebo) discloses skin care products comprising a parent protease (Bacillus protease with the trade name Esperase®) coupled to polysaccharides through a triazine ring to improve the thermal and preservation stability. The coupling technique used is also described in the above mentioned GB patent no. 1,183,257 (Crook et al.).

JP 3083908 describes a skin cosmetic material which contains a transglutaminase from guinea pig liver modified with one or more water-soluble, substances such as PEG, starch, cellulose etc. The modification is performed by activating the polymeric molecules and coupling them to the enzyme. The composition is stated to be mild to the skin.

However, it is not always possible to readily couple polymeric molecules to polypeptides and enzymes. Further, there is still a need for polypeptide-polymer conjugates with an even more reduced immunogenicity and/or allergenicity.

SUMMARY OF THE INVENTION

It is the object of the present invention to provide improved polypeptide-polymer conjugates suitable for industrial and pharmaceutical applications.

The term “improved polypeptide-polymer conjugates” means in the context of the present invention conjugates having a reduced immune response in humans and animals and/or a improved stability. As will be described further below the immune response is dependent on the way of challenge.

The present inventors have found that polypeptides, such as enzymes, may be made less immunogenic and/or allergenic by adding and/or removing one or more attachment groups on the surface of the parent polypeptide to be coupled to polymeric molecules.

When introducing pharmaceutical polypeptide directly into the circulatory system (i.e. bloodstream) the potential risk is an immunogenic response in the form of mainly IgG, IgA and/or IgM antibodies. In contrast hereto, industrial polypeptides, such as enzymes used as a functional ingredient in e.g. detergents, are not intended to enter the circulatory system. The potential risk in connection with industrial polypeptides is inhalation causing an allergenic response in the form of mainly IgE antibody formation.

Therefore, in connection with industrial polypeptides the potential risk is respiratory allergenicity caused by inhalation, intratracheal and intranasal presentation of polypeptides.

The main potential risk of pharmaceutical polypeptides is immunogenicity caused by, intradermal, intravenous, or subcutaneous presentation of the polypeptide.

It is to be understood that reducing the “immunogenicity” and reducing the “respiratory allergenicity” are two very different problems based on different routes of exposure and on two very different immunological mechanisms:

The term “immunogenicity” used in connection with the present invention may be referred to as allergic contact dermatitis in a clinical setting and is a cell mediated delayed immune response to chemicals that contact and penetrate the skin. This cell mediated reaction is also termed delayed contact hypersensitivity (type IV reaction according to Gell and Combs classification of immune mechanisms in tissue damage).

The term “allergenicity” or “respiratory allergenicity” is an immediate anaphylactic reaction (type I antibody-mediated reaction according to Gell and Combs) following inhalation of e.g. polypeptides.

According to the present invention it is possible to provide polypeptides with a reduced immune response and/or improved stability, which has a substantially retained residual activity.

The allergic and the immunogenic response are in one term, at least in the context of the present invention called the “immune response”.

In the first aspect the invention relates to a polypeptide-polymer conjugate having

a) one or more additional polymeric molecules coupled to the polypeptide having been modified in a manner to increase the number of attachment groups on the surface of the polypeptide in comparison to the number of attachment groups available on the corresponding parent polypeptide, and/or

b) one or more fewer polymeric molecules coupled to the polypeptide having been modified in a manner to decrease the number of attachment groups at or close to the functional site(s) of the polypeptide in comparison to the number of attachment groups available on the corresponding parent polypeptide.

The term “parent polypeptide” refers to the polypeptide to be modified by coupling to polymeric molecules. The parent polypeptide may be a naturally-occurring (or wild-type) polypeptide or may be a variant thereof prepared by any suitable means. For instance, the parent polypeptide may be a variant of a naturally-occurring polypeptide which has been modified by substitution, deletion or truncation of one or more amino acid residues or by addition or insertion of one or more amino acid residues to the amino acid sequence of a naturally-occurring polypeptide.

A “suitable attachment group” means in the context of the present invention any amino acid residue group on the surface of the polypeptide capable of coupling to the polymeric molecule in question.

Preferred attachment groups are amino groups of Lysine residues and the N-terminal amino group. Polymeric molecules may also be coupled to the carboxylic acid groups (—COOH) of amino acid residues in the polypeptide chain located on the surface. Carboxylic acid attachment groups may be the carboxylic acid group of Aspartate or Glutamate and the C-terminal COOH-group.

A “functional site” means any amino acid residues and/or cofactors which are known to be essential for the performance of the polypeptide, such as catalytic activity, e.g. the catalytic triad residues, Histidine, Aspartate and Serine in Serine proteases, or e.g. the heme group and the distal and proximal Histidines in a peroxidase such as the Arthromyces ramosus peroxidase.

In the second aspect the invention relates to a method for preparing improved polypeptide-polymer conjugates comprising the steps of:

a) identifying amino acid residues located on the surface of the 3D structure of the parent polypeptide in question,

b) selecting target amino acid residues on the surface of said 3D structure of said parent polypeptide to be mutated,

c) i) substituting or inserting one or more amino acid residues selected in step b) with an amino acid residue having a suitable attachment group, and/or ii) substituting or deleting one or more amino acid residues selected in step b) at or close to the functional site(s),

d) coupling polymeric molecules to the mutated polypeptide.

The invention also relates to the use of a conjugate of the invention and the method of the invention for reducing the immunogenicity of pharmaceuticals and reducing the allergenicity of industrial products.

Finally the invention relates to compositions comprising a conjugate of the invention and further ingredients used in industrial products or pharmaceuticals.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 shows the anti-lipase serum antibody levels after 5 weekly immunizations with i) control ii) unmodified lipase variant, iii) lipase variant-SPEG. (X: log(serum dilution); Y optical Density (490/620)).

DETAILED DESCRIPTION OF THE INVENTION

It is the object of the present invention to provide improved polypeptide-polymer conjugates suitable for industrial and pharmaceutical applications.

Even though polypeptides used for pharmaceutical applications and industrial application can be quite different the principle of the present invention may be tailored to the specific type of parent polypeptide (i.e. enzyme, hormone peptides etc.).

The inventors of the present invention have provided improved polypeptide-polymer conjugates with a reduced immune response in comparison to conjugates prepared from the corresponding parent polypeptides.

The present inventors have found that polypeptides, such as enzymes, may be made less immunogenic and/or less allergenic by adding one or more attachment groups on the surface of the parent polypeptide. In addition thereto the inventors have found that a higher percentage of maintained residual functional activity may be obtained by removing attachment groups at or close to the functional site(s).

In the first aspect the invention relates to an improved polypeptide-polymer conjugate having

a) one or more additional polymeric molecules coupled to the polypeptide having been modified in a manner to increase the number of attachment groups on the surface of the polypeptide in comparison to the number of attachment groups available on the corresponding parent polypeptide, and/or

b) one or more fewer polymeric molecules coupled to the polypeptide having been modified in a manner to decrease the number of attachment groups at or close to the functional site(s) of the polypeptide in comparison to the number of attachment groups available on the corresponding parent polypeptide.

Whether the attachment groups should be added and/or removed depends on the specific parent polypeptide.

a) Addition of Attachment Groups

There may be a need for further attachment groups on the polypeptide if only few attachment groups are available on the surface of the parent polypeptide. The addition of one or more attachment groups by substituting or inserting one or more amino acid residues on the surface of the parent polypeptide increases the number of polymeric molecules which may be attached in comparison to the corresponding parent polypeptide. Conjugates with an increased number of polymeric molecules attached thereto are generally seen to have a reduced immune response in comparison to the corresponding conjugates having fewer polymeric molecules coupled thereto.

Any available amino acid residues on the surface of the polypeptide, preferentially not being at or close to the functional site(s), such as the active site(s) of enzymes, may in principle be subject to substitution and/or insertion to provide additional attachment groups.

As will be described further below the location of the additional coupled polymeric molecules may be of importance for the reduction of the immune response and the percentage of maintained residual functional activity of the polypeptide itself.

A conjugate of the invention may typically have from 1 to 25, preferentially 1 to 10 or more additional polymeric molecules coupled to the surface of the polypeptide in comparison to the number of polymeric molecules of a conjugate prepared on the basis of the corresponding parent polypeptide.

However, the optimal number of attachment groups to be added depends (at least partly) on the surface area (i.e. molecular weight) of the parent polypeptide to be shielded by the coupled polymeric molecules, and also on the number of already available attachment groups on the parent polypeptide.

b) Removing Attachment Groups

In the case of enzymes or other polypeptides performing their function by interaction with a substrate or the like, polymeric molecules coupled to the polypeptide might be impeded by the interaction between the polypeptide and its substrate or the like, if they are coupled at or close to the functional site(s) (i.e. active site of enzymes). This will most probably cause reduced activity.

In the case of enzymes having one or more polymeric molecules coupled at or close to the active site a substantial loss of residual enzymatic activity can be expected. Therefore, according to the invention conjugates may be constructed to maintain a higher percentage of residual enzymatic activity in comparison to a corresponding conjugates prepared on the basis of the parent enzyme in question. This may be done by substituting and/or deleting attachment groups at or close to the active site, hereby increasing the substrate affinity by improving the accessibility of the substrate in the catalytic cleft.

An enzyme-polymer conjugate of the invention may typically have from 1 to 25, preferably 1 to 10 fewer polymeric molecules coupled at or close to the active site in comparison to the number of polymeric molecules of a conjugate prepared on the basis of the corresponding parent polypeptide.

As will be explained below “at or close to” the functional site(s) means that no polymeric molecule(s) should be coupled within 5 Å, preferably 8 Å, especially 10 Å of the functional site(s).

Removal of attachment groups at or close to the functional site(s) of the polypeptide may advantageously be combined with addition of attachment groups in other parts of the surface of the polypeptide.

The total number of attachment groups may this way be unchanged, increased or decreased. However the location(s) of the total number of attachment group(s) is (are) improved assessed by the reduction of the immune response and/or percentage of maintained residual activity. Improved stability may also be obtained this way.

The Number of Attachment Groups

Generally seen the number of attachment groups should be balanced to the molecular weight and/or surface area of the polypeptide. The more heavy the polypeptide is the more polymeric molecules should be coupled to the polypeptide to obtain sufficient shielding of the epitope(s) responsible for antibody formation.

Therefore, if the parent polypeptide molecule is relatively light (e.g. 1 to 35 kDa) it may be advantageous to increase the total number of coupled polymeric molecules (outside the functional site(s)) to a total between 4 and 20.

If the parent polypeptide molecules is heavier, for instance 35 to 60 kDa, the number of coupled polymeric molecules (outside the functional site(s)) may advantageously be increased to 7 to 40, and so on.

The ratio between the molecular weight (Mw) of the polypeptide in question and the number of coupled polymeric molecules considered to be suitable by the inventors is listed below in Table 1.

TABLE 1 Number of polymeric Molecular weight of parent molecules coupled to the polypeptide (M_(w)) kDa polypeptide  1 to 35 4-20 35 to 60 7-40 60 to 80 10-50   80 to 100 15-70  more than 100 more than 20

Reduced Immune Response vs. Maintained Residual Enzymatic Activity

Especially for enzymes, in comparison to many other types of polypeptides, there is a conflict between reducing the immune response and maintaining a substantial residual enzymatic activity as the activity of enzymes are connected with interaction between a substrate and the active site often present as a cleft in the enzyme structure.

Without being limited to any theory it is believed that the loss of enzymatic activity of enzyme-polymer conjugates might be a consequence of impeded access of the substrate to the active site in the form of spatial hindrance of the substrate by especially bulky and/or heavy polymeric molecules to the catalytic cleft. It might also, at least partly, be caused by disadvantageous minor structural changes of the 3D structure of the enzyme due to the stress made by the coupling of the polymeric molecules.

Maintained Residual Activity

A polypeptide-polymer conjugates of the invention has a substantially maintained functional activity.

A “substantially” maintained functional activity is in the context of the present invention defined as an activity which is at least between 20% and 30%, preferably between 30% and 40%, more preferably between 40% and 60%, better from 60% up to 80%, even better from 80% up to about 100%, in comparison to the activity of the conjugates prepared on the basis of corresponding parent polypeptides.

In the case of polypeptide-polymer conjugates of the invention where no polymeric molecules are coupled at or close to the functional site(s) the residual activity may even be up to 100% or very close thereto. If attachment group(s) of the parent polypeptide is(are) removed from the functional site the activity might even be more than 100% in comparison to modified (i.e. polymer coupled) parent polypeptide conjugate.

Position of Coupled Polymeric Molecules

To obtain an optimally reduced immune response (i.e. immunogenic and allergenic response) the polymeric molecules coupled to the surface of the polypeptide in question should be located in a suitable distance from each other.

In a preferred embodiment of the invention the parent polypeptide is modified in a manner whereby the polymeric molecules are spread broadly over the surface of the polypeptide. In the case of the polypeptide in question has enzymatic activity it is preferred to have as few as possible, especially none, polymeric molecules coupled at or close to the area of the active site.

In the present context “spread broadly over the surface of the polypeptide” means that the available attachment groups are located so that the polymeric molecules shield different parts of the surface, preferably the whole or close to the whole surface area away from the functional site(s), to make sure that epitope(s) are shielded and hereby not recognized by the immune system or its antibodies.

The area of antibody-polypeptide interaction typically covers an area of 500 Å², as described by Sheriff et al. (1987), Proc. Natl. Acad. Sci. USA 84, p. 8075-8079. 500 Å² corresponds to a rectangular box of 25 Å×20 Å or a circular region of radius 12.6 Å. Therefore, to prevent binding of antibodies to the epitope(s) to the polypeptide in question it is preferred to have a maximum distance between two attachment groups around 10 Å.

Consequently, amino acid residues which are located in excess of 10 Å away from already available attachment groups are suitable target residues. If two or more attachment groups on the polypeptide are located very close to each other it will in most cases result in that only one polymeric molecule will be coupled.

To ensure a minimal loss of functional activity it is preferred not to couple polymeric molecules at or close to the functional site(s). Said distance depends at least partly on the bulkiness of the polymeric molecules to be coupled, as impeded access by the bulky polymeric molecules to the functional site is undesired. Therefore, the more bulky the polymeric molecules are the longer should the distance from the functional site to the coupled polymeric molecules be.

To maintain a substantial functional activity of the polypeptide in question attachment groups located within 5 Å, preferred 8 Å, especially 10 Å from such functional site(s) should be left uncoupled and may therefore advantageously be removed or changed by mutation. Functional residues should normally not be mutated/removed, even though they potentially can be the target for coupling polymeric molecules. In said case it may thus be advantageous to choose a coupling chemistry involving different attachment groups.

Further, to provide a polypeptide having coupled polymeric molecules at (a) known epitope(s) recognizable by the immune system or close to said epitope(s) specific mutations at such sites are also considered advantageous according to the invention. If the position of the epitope(s) is(are) unknown it is advantageous to couple several or many polymeric molecules to the polypeptide.

As also mentioned above it is preferred that said attachment groups are spread broadly over the surface.

The Attachment Group

Virtually all ionized groups, such as the amino groups of Lysine residues, are located on the surface of the polypeptide molecule (see for instance Thomas E. Creighton, (1993), “Proteins”, W. H. Freeman and Company, New York).

Therefore, the number of readily accessible attachment groups (e.g. amino groups) on a modified or parent polypeptide equals generally seen the number of Lysine residues in the primary structure of the polypeptide plus the N-terminus amino group.

The chemistry of coupling polymeric molecules to amino groups are quite simple and well established in the art. Therefore, it is preferred to add and/or remove Lysine residues (i.e. attachment groups) to/from the parent polypeptide in question to obtain improved conjugates with reduced immunogenicity and/or allergenicity and/or improved stability and/or high percentage maintained functional activity.

Polymeric molecules may also be coupled to the carboxylic groups (—COOH) of amino acid residues on the surface of the polypeptide. Therefore, if using carboxylic groups (including the C-terminal group) as attachment groups addition and/or removal of Aspartate and Glutamate residues may also be suitable according to the invention.

If using other attachment groups, such as —SH groups, they may be added and/or removed analogously.

Substitution of the amino acid residues is preferred over insertion, as the impact on the 3D structure of the polypeptide normally will be less pronounced.

Preferred substitutions are conservative substitutions. In the case of increasing the number of attachment groups the substitution may advantageously be performed at a location having a distance of 5 Å, preferred 8 Å, especially 10 Å from the functional site(s) (active site for enzymes).

An example of a suitable conservative substitution to obtain an additional amino attachment group is an Arginine to Lysine substitution. Examples of conservative substitutions to obtain additional carboxylic attachment groups are Aspargine to Aspartate/Glutamate or Glutamine to Aspartate/Glutamate substitutions. To remove attachment groups a Lysine residue may be substituted with an Arginine and so on.

The Parent Polypeptide

In the context of the present invention the term “polypeptides” includes proteins, peptides and/or enzymes for pharmaceutical or industrial applications. Typically the polypeptides in question have a molecular weight in the range between about 1 to 100 kDa, often 15 kDa and 100 kDa.

Pharmaceutical Polypeptides

The term “pharmaceutical polypeptides” is defined as polypeptides, including peptides, such as peptide hormones, proteins and/or enzymes, being physiologically active when introduced into the circulatory system of the body of humans and/or animals.

Pharmaceutical polypeptides are potentially immunogenic as they are introduced into the circulatory system.

Examples of “pharmaceutical polypeptides” contemplated according to the invention include insulin, ACTH, glucagon, somatostatin, somatotropin, thymosin, parathyroid hormone, pigmentary hormones, somatomedin, erythropoietin, luteinizing hormone, chorionic gonadotropin, hypothalmic releasing factors, antidiuretic hormones, thyroid stimulating hormone, relaxin, interferon, thrombopoietin (TPO) and prolactin.

Industrial Polypeptides

Polypeptides used for industrial applications often have an enzymatic activity. Industrial polypeptides (e.g. enzymes) are (in contrast to pharmaceutical polypeptides) not intended to be introduced into the circulatory system of the body.

It is not very like that industrial polypeptides, such as enzymes used as ingredients in industrial compositions and/or products, such as detergents and personal care products, including cosmetics, come into direct contact with the circulatory system of the body of humans or animals, as such enzymes (or products comprising such enzymes) are not injected (or the like) into the bloodstream.

Therefore, in the case of the industrial polypeptide the potential risk is respiratory allergy (i.e. IgE response) as a consequence of inhalation to polypeptides through the respiratory passage.

In the context of the present invention “industrial polypeptides” are defined as polypeptides, including peptides, proteins and/or enzymes, which are not intended to be introduced into the circulatory system of the body of humans and/or animals.

Examples of such polypeptides are polypeptides, especially enzymes, used in products such as detergents, household article products, agrochemicals, personal care products, such as skin care products, including cosmetics and toiletries, oral and dermal pharmaceuticals, composition use for processing textiles, compositions for hard surface cleaning, and compositions used for manufacturing food and feed etc.

Enzymatic Activity

Pharmaceutical or industrial polypeptides exhibiting enzymatic activity will often belong to one of the following groups of enzymes including Oxidoreductases (E.C. 1, “Enzyme Nomenclature, (1992), Academic Press, Inc.), such as laccase and Superoxide dismutase (SOD); Transferases, (E.C. 2), such as transglutaminases (TGases); Hydrolases (E.C. 3), including proteases, especially subtilisins, and lipolytic enzymes; Isomerases (E.C. 5), such as Protein disulfide Isomerases (PDI).

Hydrolases

Proteolytic Enzymes

Contemplated proteolytic enzymes include proteases selected from the group of Aspartic proteases, such pepsins, Cysteine proteases, such as Papain, Serine proteases, such as subtilisins, or metallo proteases, such as NEUTRASE®.

Specific examples of parent proteases include PD498 (WO 93/24623 and SEQ ID NO. 2), SAVINASE® (von der Osten et al., (1993), Journal of Biotechnology, 28, p. 55+, SEQ ID NO 3), Proteinase K (Gunkel et al., (1989), Eur. J. Biochem, 179, p. 185-194), Proteinase R (Samal et al, (1990), Mol. Microbiol, 4, p. 1789-1792), Proteinase T (Samal et al., (1989), Gene, 85, p. 329-333), Subtilisin DY (Betzel et al. (1993), Arch. Biophys, 302, no. 2, p. 499-502), Lion Y (JP 04197182-A), RENNILASE® (Available from Novo Nordisk A/S), JA16 (WO 92/17576), ALCALASE® (a natural subtilisin Carlberg variant) (von der Osten et al., (1993), Journal of Biotechnology, 28, p. 55+).

Lipolytic Enzymes

Contemplated lipolytic enzymes include Humicola lanuginosa lipases, e.g. the one described in EP 258 068 and EP 305 216 (See SEQ ID NO 6 below), Humicola insolens, a Rhizomucor miehei lipase, e.g. as described in EP 238 023, Absidia sp. lipolytic enzymes (WO 96/13578), a Candida lipase, such as a C. antarctica lipase, e.g. the C. antarctica lipase A or B described in EP 214 761, a Pseudomonas lipase such as a P. alcaligenes and P. pseudoalcaligenes lipase, e.g. as described in EP 218 272, a P. cepacia lipase, e.g. as described in EP 331 376, a Pseudomonas sp. lipase as disclosed in WO 95/14783, a Bacillus lipase, e.g. a B. subtilis lipase (Dartois et al., (1993) Biochemica et Biophysica acta 1131, 253-260), a B. stearothermophilus lipase (JP 64/744992) and a B. pumilus lipase (WO 91/16422). Other types of lipolytic enzymes include cutinases, e.g. derived from Pseudomonas mendocina as described in WO 88/09367, or a cutinase derived from Fusarium solani pisi (e.g. described in WO 90/09446).

Oxidoreductases

Laccases

Contemplated laccases include Polyporus pinisitus laccase (WO 96/00290), Myceliophthora laccase (WO 95/33836) Scytalidium laccase (WO 95/338337), and Pyricularia oryzae laccase (Available from Sigma).

Peroxidase

Contemplated peroxidases include B. pumilus peroxidases (WO 91/05858), Myxococcaceae peroxidase (WO 95/11964), Coprinus cinereus (WO 95/10602) and Arthromyces ramosus peroxidase (Kunishima et al. (1994), J. Mol. Biol. 235, p. 331-344).

Transferases

Transglutaminases

Suitable transferases include any transglutaminases disclosed in WO 96/06931 (Novo Nordisk A/S) and WO 96/22366 (Novo Nordisk A/S).

Isomerases

Protein Disulfide Isomerase

Without being limited thereto suitable protein disulfide isomerases include PDIs described in WO 95/01425 (Novo Nordisk A/S).

The Polymeric Molecule

The polymeric molecules coupled to the polypeptide may be any suitable polymeric molecule, including natural and synthetic homo-polymers, such as polyols (i.e. poly-OH), polyamines (i.e. poly-NH₂) and polycarboxyl acids (i.e. poly—COOH), and further hetero-polymers i.e. polymers comprising one or more different coupling groups e.g. a hydroxyl group and amine groups.

Examples of suitable polymeric molecules include polymeric molecules selected from the group comprising polyalkylene oxides (PAO), such as polyalkylene glycols (PAG), including polyethylene glycols (PEG), methoxypolyethylene glycols (mPEG) and polypropylene glycols, PEG-glycidyl ethers (Epox-PEG), PEG-oxycarbonylimidazole (CDI-PEG), branched PEGS, poly-vinyl alcohol (PVA), poly-carboxylates, polyvinlypyrrlidone poly-D,L-amino acids, polyethylene-co-maleic acid anhydride, polystyrene-co-malic acid anhydride dextrans including carboxymethyl-dextrans, heparin, homologous albumin, celluloses, including methylcellulose, carboxymethylcellulose, ethylcellulose, hydroxyethylcellulose carboxyethylcellulose and hydroxypropylcellulose, hydrolysates of chitosan, starches such as hydroxyethyl-starches and hydroxy propyl-starches, glycogen, agaroses and derivatives thereof, guar gum, pullulan, inulin, xanthan gum, carrageenin, pectin, alginic acid hydrolysates and bio-polymers.

Preferred polymeric molecules are non-toxic polymeric molecules such as (m)polyethylene glycol ((m)PEG) which further requires a relatively simple chemistry for its covalently coupling to attachment groups on the enzyme's surface.

Generally seen polyalkylene oxides (PAO), such as polyethylene oxides, such as PEG and especially mPEG, are the preferred polymeric molecules, as these polymeric molecules, in comparison to polysaccharides such as dextran, pullulan and the like, have few reactive groups capable of cross-linking.

Even though all of the above mentioned polymeric molecules may be used according to the invention the methoxypolyethylene glycols (mPEG) may advantageously be used. This arises from the fact that methoxyethylene glycols have only one reactive end capable of conjugating with the enzyme. Consequently, the risk of cross-linking is less pronounced. Further, it makes the product more homogeneous and the reaction of the polymeric molecules with the enzyme easier to control.

Preparation of Enzyme Variants

Enzyme variants to be conjugated may be constructed by any suitable method. A number of methods are well established in the art. For instance enzyme variants according to the invention may be generated using the same materials and methods described in e.g. WO 89/06279 (Novo Nordisk A/S), EP 130,756 (Genentech), EP 479,870 (Novo Nordisk A/S), EP 214,435 (Henkel), WO 87/b4461 (Amgen), WO 87/05050 (Genex), EP application no. 87303761 (Genentech), EP 260,105 (Genencor), WO 88/06624 (Gist-Brocades NV), WO 88/07578 (Genentech), WO 20 88/08028 (Genex), WO 88/08033 (Amgen), WO 88/08164 (Genex), Thomas et al. (1985) Nature, 318 375-376; Thomas et al. (1987) J. Mol. Biol., 193, 803-813; Russel and Fersht (1987) Nature 328 496-500.

Generation of Site Directed Mutations

Prior to mutagenesis the gene encoding the polypeptide of interest must be cloned in a suitable vector. Methods for generating mutations in specific sites is described below.

Once the polypeptide encoding gene has been cloned, and desirable sites for mutation identified and the residue to substitute for the original ones have been decided, these mutations can be introduced using synthetic oligonucleotides.

These oligonucleotides contain nucleotide sequences flanking the desired mutation sites; mutant nucleotides are inserted during oligo-nucleotide synthesis. In a preferred method, Site-directed mutagenesis is carried out by SOE-PCR mutagenesis technique described by Kammann et al. (1989) Nucleic Acids Research 17(13), 5404, and by Sarkar G. and Sommer, S. S. (1990); Biotechniques 8, 404-407.

Activation of Polymers

If the polymeric molecules to be conjugated with the polypeptide in question are not active it must be activated by the use of a suitable technique. It is also contemplated according to the invention to couple the polymeric molecules to the polypeptide through a linker. Suitable linkers are well-known to the skilled person.

Methods and chemistry for activation of polymeric molecules as well as for conjugation of polypeptides are intensively described in the literature. Commonly used methods for activation of insoluble polymers include activation of functional groups with cyanogen bromide, periodate, glutaraldehyde, biepoxides, epichlorohydrin, divinylsulfone, carbodiimide, sulfonyl halides, trichlorotriazine etc. (see R. F. Taylor, (1991), “Protein immobilization Fundamentals and applications”, Marcel Dekker, N.Y.; S. S. Wong, (1992), “Chemistry of Protein Conjugation and Crosslinking”, CRC Press, Boca Raton; G. T. Hermanson et al., (1993), “Immobilized Affinity Ligand Techniques”, Academic Press, N.Y.). Some of the methods concern activation of insoluble polymers but are also applicable to activation of soluble polymers e.g. periodate, trichlorotriazine, sulfonylhalides, divinylsulfone, carbodiimide etc. The functional groups being amino, hydroxyl, thiol, carboxyl, aldehyde or sulfydryl on the polymer and the chosen attachment group on the protein must be considered in choosing the activation and conjugation chemistry which normally consist of i) activation of polymer, ii) conjugation, and iii) blocking of residual active groups.

In the following a number of suitable polymer activation methods will be described shortly. However, it is to be understood that also other methods may be used.

Coupling polymeric molecules to the free acid groups of poly-peptides may be performed with the aid of diimide and for example amino-PEG or hydrazino-PEG (Pollak et al., (1976), J. Amr. Chem. Soc., 98, 289-291) or diazoacetate/amide (Wong et al., (1992), “Chemistry of Protein Conjugation and Crosslinking”, CRC Press).

Coupling polymeric molecules to hydroxy groups are generally very difficult as it must be performed in water. Usually hydrolysis predominates over reaction with hydroxyl groups.

Coupling polymeric molecules to free sulfhydryl groups can be reached with special groups like maleimido or the ortho-pyridyl disulfide. Also vinylsulfone (U.S. Pat. No. 5,414,135, (1995), Snow et al.) has a preference for sulfhydryl groups but is not as selective as the other mentioned.

Accessible Arginine residues in the polypeptide chain may be targeted by groups comprising two vicinal carbonyl groups.

Techniques involving coupling electrophilically activated PEGs to the amino groups of Lysines may also be useful. Many of the usual leaving groups for alcohols give rise to an amine linkage. For instance, alkyl sulfonates, such as tresylates (Nilsson et al., (1984), Methods in Enzymology vol. 104, Jacoby, W. B., Ed., Academic Press: Orlando, p. 56-66; Nilsson et al., (1987), Methods in Enzymology vol. 135; Mosbach, K., Ed.; Academic Press: Orlando, pp. 65-79; Scouten et al., (1987), Methods in Enzymology vol. 135, Mosbach, K., Ed., Academic Press: Orlando, 1987; pp 79-84; Crossland et al., (1971), J. Amr. Chem. Soc. 1971, 93, pp. 4217-4219), mesylates (Harris, (1985), supra; Harris et al., (1984), J. Polym. Sci. Polym. Chem. Ed. 22, pp 341-352), aryl sulfonates like tosylates, and para-nitrobenzene sulfonates can be used.

Organic sulfonyl chlorides, e.g. Tresyl chloride, effectively converts hydroxy groups in a number of polymers, e.g. PEG, into good leaving groups (sulfonates) that, when reacted with nucleophiles like amino groups in polypeptides allow stable linkages to be formed between polymer and polypeptide. In addition to high conjugation yields, the reaction conditions are in general mild (neutral or slightly alkaline pH, to avoid denaturation and little or no disruption of activity), and satisfy the non-destructive requirements to the polypeptide.

Tosylate is more reactive than the mesylate but also more unstable decomposing into PEG, dioxane, and sulfonic acid (zalipsky, (1995), Bioconjugate Chem., 6, 150-165). Epoxides may also been used for creating amine bonds but are much less reactive than the above mentioned groups.

Converting PEG into a chloroformate with phosgene gives rise to carbamate linkages to Lysines. This theme can be played in many variants substituting the chlorine with N-hydroxy succinimide (U.S. Pat. No. 5,122,614, (1992); Zalipsky et al., (1992), Biotechnol. Appl. Biochem., 15, p. 100-114; Monfardini et al., (1995), Bioconjugate Chem., 6, 62-69, with imidazole (Allen et al., (1991), Carbohydr. Res., 213, pp 309-319), with para-nitrophenol, DMAP (EP 632 082 A1, (1993), Looze, Y.) etc. The derivatives are usually made by reacting the chloroformate with the desired leaving group. All these groups give rise.to carbamate linkages to the peptide.

Furthermore, isocyanates and isothiocyanates may be employed yielding ureas and thioureas, respectively.

Amides may be obtained from PEG acids using the same leaving groups as mentioned above and cyclic imide thrones (U.S. Pat. No. 5,349,001, (1994), Greenwald et al.). The reactivity of these compounds are very high but may make the hydrolysis to fast.

PEG succinate made from reaction with succinic anhydride can also be used. The hereby comprised ester group make the conjugate much more susceptible to hydrolysis (U.S. Pat. No. 5,122,614, (1992), Zalipsky). This group may be activated with N-hydroxy succinimide.

Furthermore, a special linker can be introduced. The oldest being cyanuric chloride (Abuchowski et al., (1977), J. Biol. Chem., 252, 3578-3581; U.S. Pat. No. 4,179,337, (1979), Davis et al.; Shafer et al., (1986), J. Polym. Sci. Polym. Chem. Ed., 24, 375-378.

Coupling of PEG to an aromatic amine followed by, diazotization yields a very reactive diazonium salt which in situ can be reacted with a peptide. An amide linkage may also be obtained by reacting an azlactone derivative of PEG (U.S. Pat. No. 5,321,095, (1994), Greenwald, R. B.) thus introducing an additional amide linkage.

As some peptides do not comprise many Lysines it may be advantageous to attach more than one PEG to the same Lysine. This can be done e.g. by the use of 1,3-diamino-2-propanol.

PEGs may also be attached to the amino-groups of the enzyme with carbamate linkages (WO 95111924, Greenwald et al.). Lysine residues may also be used as the backbone.

The coupling technique used in the examples is, the N-succinimidyl carbonate conjugation technique, described in WO 90/13590 (Enzon).

Method for Preparing Improved Conjugates

It is also an object of the invention to provide a method for preparing improved polypeptide-polymer conjugates comprising the steps of:

a) identifying amino acid residues located on the surface of the 3D structure of the parent polypeptide in question,

b) selecting target amino acid residues on the surface of said 3D structure of said parent polypeptide to be mutated,

c) i) substituting or inserting one or more amino acid residues selected in step b) with an amino acid residue having a suitable attachment group, and/or ii) substituting or deleting one or more amino acid residues selected in step b) at or close to the functional site(s),

d) coupling polymeric molecules to the mutated polypeptide.

Step a) Identifyinq Amino Acid Residues Located on the Surface of the Parent Polypeptide

3-dimensional Structure (3D-structure)

To perform the method of the invention a 3-dimensional structure of the parent polypeptide in question is required. This structure may for example be an X-ray structure, an NMR structure or a model-built structure. The Brookhaven Databank is a source of X-ray- and NMR-structures.

A model-built structure may be produced by the person skilled in the art if one or more 3D-structure(s) exist(s) of homologous polypeptide(s) sharing at least 30% sequence identity with the polypeptide in question. Several software packages exist which may be employed to construct a model structure. One example is the Homology 95.0 package from Biosym.

Typical actions required for the construction of a model structure are: alignment of homologous sequences for which 3D-structures exist, definition of Structurally Conserved Regions (SCRs), assignment of coordinates to SCRs, search for structural fragments/loops in structure databases to replace Variable Regions, assignment of coordinates to these regions, and structural refinement by energy minimization. Regions containing large inserts (≧3 residues) relative to the known 3D-structures are known to be quite difficult to model, and structural predictions must be considered with care.

Having obtained the 3D-structure of the polypeptide in question, or a model of the structure based on homology to known structures, this structure serves as an essential prerequisite for the fulfillment of the method described below.

Step b) Selection of Target Amino Acid Residues for Mutation

Target amino acid residues to be mutated are according to the invention selected in order to obtain additional or fewer attachment groups, such as free amino groups (—NH₂) or free carboxylic acid groups (—COOH), on the surface of the polypeptide and/or to obtain a more complete and broadly spread shielding of the epitope(s) on the surface of the polypeptide.

Conservative Substitution

It is preferred to make conservative substitutions in the polypeptide, as conservative substitutions secure that the impact of the mutation on the polypeptide structure is limited.

In the case of providing additional amino groups this may be done by substitution of Arginine to Lysine, both residues being positively charged, but only the Lysine having a free amino group suitable as an attachment group.

In the case of providing additional carboxylic acid groups the conservative substitution may for instance be an Aspargine to Aspartic acid or Glutamine to Glutamic acid substitution. These residues resemble each other in size and shape, except from the carboxylic groups being present on the acidic residues.

In the case of providing fewer attachment groups, e.g. at or close to the active site, a Lysine may be substituted with an Arginine, and so on.

Which amino acids to substitute depends in principle on the coupling chemistry to be applied.

Non-conservative Substitution

The mutation may also be on target amino acid residues which are less/non-conservative. Such mutation is suitable for obtaining a more complete and broadly spread shielding of the polypeptide surface than can be obtained by the conservative substitutions.

The method of the invention is first described in general terms, and subsequently using specific examples.

Note the use of the following terms:

Attachment_residue: residue(s) which can bind polymeric molecules, e.g. Lysines (amino group) or Aspartic/Glutamic acids (carboxylic groups). N- or C-terminal amino/carboxylic groups are to be included where relevant. Mutation_residue: residue(s) which is to be mutated, e.g. Arginine or Aspargine/Glutamine. Essential_catalytic_residues: residues which are known to be essential for catalytic function, e.g. the catalytic triad in Serine proteases. Solvent_exposed_residues: These are defined as residues which are at least 5% exposed according to the BIOSYM/INSIGHT algorithm found in the module Homology 95.0. The sequence of commands are as follows:

Homology=>ProStat=>Access_Surf=>Solv_Radius 1.4; Heavy atoms only; Radii source VdW; Output: Fractional Area; Polarity source: Default. The file filename_area.tab is produced. Note: For this program to function properly all water molecules must first be removed from the structure. It looks for example like:

# PD498FINALMODEL # residue area TRP_1 136.275711 SER_2 88.188095 PRO_3 15.458788 ASN_4 95.322319 ASP_5 4.903404 PRO_6 68.096909 TYR_7 93.333252 TYR_8 31.791576 SER_9 95.983139 . . . continued

1. Identification of residues which are more than 10 Å away from the closest attachment_residue, and which are located at least 8 Å away from essential_catalytic_residues. This residue subset is called REST, and is the primary region for conservative mutation_residue to attachment_residue substitutions.

2. Identification of residues which are located in a 0-5 Å shell around subset REST, but at least 8 Å away from essential_catalytic_residues. This residue subset is called SUB5B. This is a secondary region for conservative mutation_residue to attachment_residue substitutions, as a ligand bound to an attachment_residue in SUB5B will extend into the REST region and potentially prevent epitope recognition.

3. Identification of solvent_exposed mutation_residues in REST and SUB5B as potential mutation sites for introduction of attachment_residues.

4. Use BIOSYM/INSIGHT's Biopolymer module and replace residues identified under action 3.

5. Repeat 1-2 above producing the subset RESTx. This subset includes residues which are more than 10 Å away from the nearest attachment_residue, and which are located at least 8 Å away from essential catalytic residues.

6 Identify solvent_exposed_residues in RESTx. These are potential sites for less/non-conservative mutations to introduce attachment_residues.

Step c) Substituting, Inserting or Deleting Amino Acid Residues

The mutation(s) performed in step c) may be performed by standard techniques well known in the art, such as site-directed mutagenesis (see, e.g., Sambrook et al. (1989), Sambrook et al., Molecular Cloning. A Laboratory Manual, Cold Spring Harbor, N.Y.

A general description of nucleotide substitution can be found in e.g. Ford et al., 1991, Protein Expression and Purification 2, p. 95-107.

Step d) Coupling Polymeric Molecules to the Modified Parent Enzyme

Polypeptide-polymer conjugates of the invention may be prepared by any coupling method known in the art including the above mentioned techniques.

Coupling of Polymeric Molecules to the Polypeptide in Question

If the polymeric molecules to be conjugated with the polypeptide are not active it must be activated by the use of a suitable method. The polymeric molecules may be coupled to the polypeptide through a linker. Suitable linkers are well known to the skilled person.

Methods and chemistry for activation of polymeric molecules as well as for conjugation of polypeptides are intensively described in the literature. Commonly used methods for activation of insoluble polymers include activation of functional groups with cyanogen bromide, periodate, glutaraldehyde biepoxides, epichlorohydrin, divinylsulfone, carbodiimide, sulfonyl halides, trichlorotriazine etc. (see R. F. Taylor, (1991), “Protein immobilization, Fundamentals and applications”, Marcel Dekker, N.Y.; S. S. Wong, (1992), “Chemistry of Protein Conjugation and Crosslinking”, CRC Press, Boca Raton; G. T. Hermanson et al., (1993), “Immobilized Affinity Ligand Techniques”, Academic Press, N.Y.). Some of the methods concern activation of insoluble polymers but are also applicable to activation of soluble polymers e.g. periodate, trichlorotriazine, sulfonylhalides, divinylsulfone, carbodiimide etc. The functional groups being amino, hydroxyl, thiol, carboxyl, aldehyde or sulfydryl on the polymer and the chosen attachment group on the protein must be considered in choosing the activation and conjugation chemistry which normally consist of i) activation of polymer, ii) conjugation, and iii) blocking of residual active groups.

In the following a number of suitable polymer activation methods will be described shortly. However, it is to be understood that also other methods may be used.

Coupling polymeric molecules to the free acid groups of enzymes can be performed with the aid of diimide and for example amino-PEG or hydrazino-PEG (Pollak et al., (1976), J. Amr. Chem. Soc., 98, 289-291) or diazoacetate/amide (Wong et al., (1992), “Chemistry of Protein Conjugation and Crosslinking”, CRC Press).

Coupling polymeric molecules to hydroxy groups are generally very difficult as it must be performed in water. Usually hydrolysis predominates over reaction with hydroxyl groups.

Coupling polymeric molecules to free sulfhydryl groups can be reached with special groups like maleimido or the ortho-pyridyl disulfide. Also vinylsulfone (U.S. Pat. No. 5,414,135, (1995), Snow et al.) has a preference for sulfhydryl groups but is not as selective as the other mentioned.

Accessible Arginine residues in the polypeptide chain may be targeted by groups comprising two vicinal carbonyl groups.

Techniques involving coupling electrophilically activated PEGs to the amino groups of Lysines are also be useful. Many of the usual leaving groups for alcohols give rise to an amine linkage. For instance, alkyl sulfonates, such as tresylates (Nilsson et al., (1984), Methods in Enzymology vol. 104, Jacoby, W. B., Ed., Academic Press: Orlando, p. 56-66; Nilsson et al., (1987), Methods in Enzymology vol. 135; Mosbach, K., Ed.; Academic Press: Orlando, pp. 65-79; Scouten et al., (1987), Methods in Enzymology vol. 135, Mosbach, K., Ed., Academic Press: Orlando, 1987; pp 79-84; Crossland et al., (1971), J. Amr. Chem. Soc. 1971, 93, pp. 4217-4219), mesylates (Harris, (1985), supra; Harris et al., (1984), J. Polym. Sci. Polym. Chem. Ed. 22, pp. 341-352), aryl sulfonates like tosylates, and para-nitrobenzene sulfonates can be used.

Organic sulfonyl chlorides, e.g. Tresyl chloride, effectively converts hydroxy groups in a number of polymers, e.g. PEG, into good leaving groups (sulfonates) that, when reacted with nucleophiles like amino groups in polypeptides allow stable linkages to be formed between polymer and polypeptide. In addition to high conjugation yields, the reaction conditions are in general mild (neutral or slightly alkaline pH, to avoid denaturation and little or no disruption of activity), and satisfy the non-destructive requirements to the polypeptide.

Tosylate is more reactive than the mesylate but also more unstable decomposing into PEG, dioxane, and sulfonic acid (Zalipsky, (1995), Bioconjugate Chem., 6, 150-165). Epoxides may also been used for creating amine bonds but are much less reactive than the above mentioned groups.

Converting PEG into a chloroformate with phosgene gives rise to carbamate linkages to Lysines. This theme can be played in many variants substituting the chlorine with N-hydroxy succinimide (U.S. Pat. No. 5,122,614, (1992); Zalipsky et al., (1992), Biotechnol. Appl. Biochem., 15, p. 100-114; Monfardini et al., (1995), Bioconjugate Chem., 6, 62-69, with imidazole (Allen et al., (1991), Carbohydr. Res., 213, pp 309-319), with para-nitrophenol, DMAP (EP 632 082 A1, (1993), Looze, Y.) etc. The derivatives are usually made by reacting the chloroformate with the desired leaving group. All these groups give rise to carbamate linkages to the peptide.

Furthermore, isocyanates and isothiocyanates may be employed yielding ureas and thioureas, respectively.

Amides may be obtained from PEG acids using the same leaving groups as mentioned above and cyclic imide thrones (U.S. Pat. No. 5,349,001, (1994), Greenwald et al.). The reactivity of these compounds are very high but may make the hydrolysis to fast.

PEG succinate made from reaction with succinic anhydride can also be used. The hereby comprised ester group make the conjugate much more susceptible to hydrolysis (U.S. Pat. No. 5,122,614, (1992), Zalipsky). This group may be activated with N-hydroxy succinimide.

Furthermore, a special linker can be introduced. The oldest being cyanuric chloride (Abuchowski et al., (1977), J. Biol. Chem., 252, 3578-3581; U.S. Pat. No. 4,179,337, (1979), Davis et al.; Shafer et al., (1986), J. Polym. Sci. Polym. Chem. Ed., 24, 375-378.

Coupling of PEG to an aromatic amine followed by diazotization yields a very reactive diazonium salt which in situ can be reacted with a peptide. An amide linkage may also be obtained by reacting an azlactone derivative of PEG (U.S. Pat. No. 5,321,095, (1994), Greenwald, R. B.) thus introducing an additional amide linkage.

As some peptides do not comprise many Lysines it may be advantageous to attach more than one PEG to the same Lysine. This can be done e.g. by the use of 1,3-diamino-2-propanol.

PEGs may also be attached to the amino-groups of the enzyme with carbamate linkages (WO 95/11924, Greenwald et al.). Lysine residues may also be used as the backbone.

Addition of Attachment Groups

Specific Examples of PD498 Variant-SPEG Conjugates

A specific example of a protease is the parent PD498 (WO 93/24623 and SEQ ID NO. 2). The parent PD498 has a molecular weight of 29 kDa.

Lysine and Arginine Residues are Located as Follows:

Distance from the active site Arginine Lysine 0-5 Å 1  5-10 Å 10-15 Å 5 6 15-20 Å 2 3 20-25 Å 1 3 total 9 12

The inventors examined which parent PD498 sites on the surface may be suitable for introducing additional attachment groups.

A. Suitable conservative Arginine to Lysine substitutions in parent PD498 may be any of R51K, R62K, R121K, R169K, R250K, R28K, R190K.

B. Suitable non-conservative substitutions in parent PD498 may be any of P6K, Y7K, S9K, A10K, Y11K, Q12K, D43K, Y44K, N45K, N65K, G87K, I88K, N209K, A211K, N216K, N217K, G218K, Y219K, S220K, Y221K, G262K.

As there is no Lysine residues at or close to the active site there is no need for removing any attachment group.

PD498 variant-SPEG conjugates may be prepared using any of the above mentioned PD498 variants as the starting material by any conjugation technique known in the art for coupling polymeric molecules to amino groups on the enzyme. A specific example is described below.

Removal of Attachment Groups

Specific Examples of BPN′ Variant-SPEG Conjugates

A specific example of a protease having an attachment group in the active site is BPN′ which has 11 attachment groups (plus an N-terminal amino group): BPN′ has a molecular weight of 28 kDa.

Lysine and Arginine Residues are Located as Follows:

Distance from the active site Arginine Lysine 0-5 Å 1  5-10 Å 10-15 Å 1 4 15-20 Å 1 4 20-25 Å 2 total 2 11

The Lysine residue located within 0-5 Å of the active site can according to the invention advantageously be removed. Specifically this may be done by a K94R substitution.

BPN′ variant-SPEG conjugates may be prepared using the above mentioned BPN′ variant as the starting material by any conjugation technique known in the art for coupling polymeric molecules to amino groups on the enzyme.

Addition and Removal of Attachment Groups

Specific Example of SAVINASE®-SPEG Conjugate

As described in Example 2 parent SAVINASE® (von der Osten et al., (1993), Journal of Biotechnology, 28, p. 55+ and SEQ ID NO. 3) may according to the invention have added a number of amino attachment groups to the surface and removed an amino attachment group close to the active site.

Any of the following substitutions in the parent SAVINASE® are sites for mutagenesis: R10K, R19K, R45K, R145K, R170K, R186K and R247K.

The substitution K94R are identified as a mutation suitable for preventing attachment of polymers close to active site. SAVINASE® variant-SPEG conjugates may be prepared using any of the above mentioned SAVINASE® variants as the starting material by any conjugation technique known in the art for coupling polymeric molecules to amino groups on the enzyme.

Addition of Attachment Groups

A Specific Examples of Humicola Lanuginosa Lipase Variants-SPEG Conjugates

Specific examples of lipase variants with reduced immunogenicity using the parent Huminocal lanuginosa DSM 4109 lipase (see SEQ ID No 6) as the backbone for substitutions are listed below.

The parent unmodified Humicola lanuginosa lipase has 8 attachment groups including the N-terminal NH₂ group and a molecular weight of about 29 kDa. A. Suitable conservative Arginine to Lysine substitutions in the parent lipase may be any of R133K, R139K, R160K, R179K, R209K, R118K and R125K.

Suitable non-conservative substitutions in the parent lipase may be any of:

A18K,G31K,T32K,N33K,G38K,A40K,D48K,T50K,E56K,D57K,S58K,G59K, V60K, G61K,D62K,T64K,L78K,N88K,G91K,N92K,L93K,S105K,G106K, V120K,P136K,G225K,L227K,V228K,P229K,P250K,F262K.

Further suitable non-conservative substitution in the Humicola lanuginosa lipase include: E87K or D254K.

Lipase variant-SPEG conjugates may be prepared using any of the above mentioned lipase variants as the starting material by any conjugation technique known in the art for coupling polymeric molecules to amino groups on the enzyme. A specific example is described below.

In Example 12 below it is shown that a conjugate of the Humicola lanuginosa lipase variant with a E87K+D254K substitutions coupled to S-PEG 15,000 has reduced immunogenic response in Balb/C mice in comparison to the corresponding parent unmodified enzyme.

Immunogenicity and Allergenicity

“Immunogenicity” is a broader term than “antigenicity” and “allergenicity”, and expresses the immune system's response to the presence of foreign substances. Said foreign substances are called immunogens, antigens and allergens depending of the type of immune response they elicit.

An “immunogen” may be defined as a substance which, when introduced into circulatory system of animals and humans, is capable of stimulating an immunologic response resulting in formation of immunoglobulin.

The term “antigen” refers to substances which by themselves are capable of generating antibodies when recognized as a non-self molecule.

Further, an “allergen” may be defined as an antigen which may give rise to allergic sensitization or an allergic response by IgE antibodies (in humans, and molecules with comparable effects in animals).

Assessment of Immunogencity

Assessment of the immunogenicity may be made by injecting animal subcutaneously to enter the immunogen into the circulation system and comparing the response with the response of the corresponding parent polypeptide.

The “circulatory system” of the body of humans and animals means, in the context of the present invention, the system which mainly consists of the heart and blood vessels. The heart delivers the necessary energy for maintaining blood circulation in the vascular system. The circulation system functions as the organism's transportation system, when the blood transports O₂, nutritious matter, hormones, and other substances of importance for the cell regulation into the tissue. Further the blood removes CO₂ from the tissue to the lungs and residual substances to e.g. the kidneys. Furthermore, the blood is of importance for the temperature regulation and the defense mechanisms of the body, which include the immune system.

A number of in vitro animal models exist for assessment of the immunogenic potential of polypeptides. Some of these models give a suitable basis for hazard assessment in man. Suitable models include a mice model.

This model, seeks to identify the immunogenic response in the form of the IgG response in Balb/C mice being injected subcutaneously with modified and unmodified polypeptides.

Also other animal models can be used for assessment of the immunogenic potential.

A polypeptide having “reduced immunogenicity” according to the invention indicates that the amount of produced antibodies, e.g. immunoglobulin in humans, and molecules with comparable effects in specific animals, which can lead to an immune response, is significantly decreased, when introduced into the circulatory system, in comparison to the corresponding parent polypeptide.

For Balb/C mice the IgG response gives a good indication of the immunigenic potential of polypeptides.

Assessment of Allergenicity

Assessment of allergenicity may be made by inhalation tests, comparing the effect of intratracheally (into the trachea) administrated parent enzymes with the corresponding modified enzymes according to the invention.

A number of in vivo animal models exist for assessment of the allegenicity of enzymes. Some of these models give a suitable basis for hazard assessment in man. Suitable models include a guinea pig model and a mouse model. These models seek to identify respiratory allergens as a function of elicitation reactions induced in previously sensitized animals. According to these models the alleged allergens are introduced intratracheally into the animals.

A suitable strain of guinea pigs, the Dunkin Hartley strain, do not as humans, produce IgE antibodies in connection with the allergic response. However, they produce another type of antibody the IgG1A and IgG1B (see e.g. Prentø, ATLA, 19, p. 8-14, 1991), which are responsible for their allergenic response to inhaled polypeptides including enzymes. Therefore, when using the Dunkin Hartley animal model, the relative amount of IgG1A and IgG1B is a measure of the allergenicity level.

The Balb/C mice strain is suitable for intratracheal exposure. Balb/C mice produce IgE as the allergic response. More details on assessing respiratory allergens in guinea pigs and mice is described by Kimber et al.,(1996), Fundamental and Applied Toxicology, 33, p. 1-10.

Other animals such as rats, rabbits etc. may also be used for comparable studies.

Composition

The invention relates to a composition comprising a polypeptide-polymer conjugate of the invention.

The composition may be a pharmaceutical or industrial composition.

The composition may further comprise other polypeptides, proteins or enzymes and/or ingredients normally used in e.g. detergents, including soap bars, household articles, agrochemicals, personal care products, including skin care compositions, cleaning compositions for e.g. contact lenses, oral and dermal pharmaceuticals, composition use for treating textiles, compositions used for manufacturing food, e.g. baking, and feed etc.

Use of the Polypeptide-polymer Conjugate

The invention also relates to the use of the method of the invention for reducing the immune response of polypeptides.

It is also an object of the invention to use the polypeptide-polymer conjugate of the invention to reduce the allergenicity of industrial products, such as detergents, such as laundry, dish wash and hard surface cleaning detergents, and food or feed products.

MATERIAL AND METHODS Materials

Enzymes:

PD498: Protease of subtilisin type shown in WO 93/24623. The sequence of PD498 is shown in SEQ ID NO. 1 and 2. SAVINASE® (Available from Novo Nordisk A/S) Humicola lanuginosa lipase: Available from Novo Nordisk as Lipolase® and is further described in EP 305,216. The DNA and protein sequence is shown in SEQ ID NO 5 and 6, respectively.

Strains:

B. subtilis 309 and 147 are variants of Bacillus lentus, deposited with the NCIB and accorded the accession numbers NCIB 10309 and 10147, and described in U.S. Pat. No. 3,723,250 incorporated by reference herein.

E. coli MC 1000 (M. J. Casadaban and S. N. Cohen (1980); J. Mol. Biol. 138 179-207), was made r⁻, m⁺ by conventional methods and is also described in U.S. patent application Ser. No. 039,298.

Vectors:

pPD498: E. coli—B. subtilis shuttle vector (described in U.S. Pat. No. 5,621,089 under section 6.2.1.6) containing the wild-type gene encoding for PD498 protease (SEQ ID NO. 2). The same vector is used for mutagenesis in E. coli as well as for expression in B. subtilis.

General Molecular Biology Methods:

Unless otherwise mentioned the DNA manipulations and transformations were performed using standard methods of molecular biology (Sambrook et al. (1989) Molecular cloning: A laboratory manual, Cold Spring Harbor lab., Cold Spring Harbor, N.Y.; Ausubel, F. M. et al. (eds.) “Current protocols in Molecular Biology”. John Wiley and Sons, 1995; Harwood, C. R., and Cutting, S. M. (eds.) “Molecular Biological Methods for Bacillus”. John Wiley and Sons, 1990). Enzymes for DNA manipulations were used according to the specifications of the suppliers.

Materials, Chemicals and Solutions:

Horse Radish Peroxidase labeled anti-rat-Ig (Dako, DK, P162, # 031; dilution 1:1000).

Mouse anti-rat IgE (Serotec MCA193; dilution 1:200).

Rat anti-mouse IgE (Serotec MCA419; dilution 1:100).

Biotin-labeled mouse anti-rat IgG1 monoclonal antibody (Zymed 03-9140; dilution 1:1000)

Biotin-labeled rat anti-mouse IgG1 monoclonal antibody (Serotec MCA336B; dilution 1:1000)

Streptavidin-horse radish peroxidase (Kirkeg{dot over (a)}rd & Perry 14-30-00; dilution 1:1000).

CovaLink NH₂ plates (Nunc, Cat# 459439)

Cyanuric chloride (Aldrich)

Acetone (Merck)

Rat anti-Mouse IgG1, biotin (SeroTec, Cat# MCA336B)

Streptavidin, peroxidase (KPL)

Ortho-Phenylene-diamine (OPD) (Kem-en-Tec)

H₂O₂, 30% (Merck)

Tween 20 (Merck)

Skim Milk powder (Difco)

H₂SO₄(Merck)

Buffers and Solutions:

Carbonate buffer (0.1 M, pH 10 (1 liter)) Na₂CO₃ 10.60 g  PBS (pH 7.2 (1 liter)) NaCl 8.00 g KCl 0.20 g K₂HPO₄ 1.04 g KH₂PO₄ 0.32 g

Washing buffer PBS, 0.05% (v/v) Tween 20

Blocking buffer PBS, 2% (wt/v) Skim Milk powder

Dilution buffer PBS, 0.05% (v/v) Tween 20, 0.5% (wt/v) Skim Milk powder

Citrate buffer (0.1M, pH 5.0-5.2 (1 liter))NaCitrate 20.60 g Citric acid 6.30 g

Activation of CovaLink Plates:

Make a fresh stock solution of 10 mg cyanuric chloride per ml acetone.

Just before use, dilute the cyanuric chloride stock solution into PBS, while stirring, to a final concentration of 1 mg/ml.

Add 100 ml of the dilution to each well of the CovaLink NH₂ plates, and incubate for 5 minutes at room temperature.

Wash 3 times with PBS.

Dry the freshly prepared activated plates at 50° C. for 30 minutes.

Immediately seal each plate with sealing tape.

Preactivated plates can be stored at room temperature for 3 weeks when kept in a plastic bag.

Sodium Borate, borax (Sigma)

3,3-Dimethyl glutaric acid (Sigma)

CaCl₂ (Sigma)

Tresyl chloride (2,2,2-triflouroethansulfonyl chloride) (Fluka)

1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) (Fluka)

N-Hydroxy succinimide (Fluka art. 56480))

Phosgene (Fluka art. 79380)

Lactose (Merck 7656)

PMSF (phenyl methyl sulfonyl flouride) from Sigma Succinyl-Alanine-Alanine-Proline-Phenylalanine-para-nitroanilide (Suc-AAPF-pNP) Sigma no. S-7388, Mw 624.6 g/mole.

Colouring Substrate:

OPD: o-phenylene-diamine, (Kementec cat no. 4260)

Test Animals:

Dunkin Hartley guinea pigs (from Charles River, Del.)

Female Balb/C mice (about 20 grams) purchased from Bomholdtgaard, Ry, Denmark.

Equipment:

XCEL II (Novex)

ELISA reader (UVmax, Molecular Devices)

HPLC (Waters)

PFLC (Pharmacia)

Superdex-75 column, Mono-Q, Mono S from Pharmacia, SW.

SLT: Fotometer from SLT LabInstruments

Size-exclusion chromatograph (Spherogel TSK-G2000 SW).

Size-exclusion chromatograph (Superdex 200, Pharmacia, SW) Amicon Cell

Enzymes for DNA Manipulations

Unless otherwise mentioned all enzymes for DNA manipulations, such as e.g. restriction endonucleases, ligases etc., are obtained from New England Biolabs. Inc.

Methods

ELISA Procedure for Determination of IqG₁ Positive Guinea Pigs

ELISA microtiter plates are coated with rabbit anti-PD498 1:8000 in carbonate buffer and incubated overnight at 4° C. The next day the plates are blocked with 2% BSA for 1 hour and washes 3 times with PBS Tween 20. 1 μg/ml PD498 is added to the plates and incubated for 1 hour, then washed 3 times with PBS Tween 20.

All guinea pig sera samples and controls are applied to the ELISA plates with 2 μl sera and 98 μl PBS, incubated for 1 hour and washed 3 times with PBS Tween 20.

Then goat anti-guinea pig IgG₁ (1:4000 in PBS buffer (Nordic Immunology 44-682)) is applied to the plates, incubated for 1 hour and washed with PBS tween 20.

Alkaline phosphatase marked rabbit anti-goat 1:8000 (Sigma A4187) is applied and incubated for 1 hour, washed 2 times in PBS Tween20 and 1 time with diethanol amine buffer.

The marked alkaline phosphatase is developed using p-nitrophenyl phosphate for 30 minutes at 37° C. or until appropriate colour has developed.

The reaction is stopped using Stop medium (K₂HPO₄/HaH₃ buffer comprising EDTA (pH 10)) and read at OD 405/650 using an ELISA reader.

Double blinds are included on all ELISA plates.

Positive and negative sera values are calculated as the average blind values added 2 times the standard deviation. This gives an accuracy of 95%.

Determination of the Molecule Weight

Electrophoretic separation of proteins was performed by standard methods using 4-20% gradient SDS poly acrylamide gels (Novex). Proteins were detected by silver staining. The molecule weight was measured relative to the mobility of Mark-12® wide range molecule weight standards from Novex.

Protease Activity

Analysis With Suc-Ala-Ala-Pro-Phe-pNa:

Proteases cleave the bond between the peptide and p-nitroaniline to give a visible yellow colour absorbing at 405 nm.

Buffer: e.g. Britton and Robinson buffer pH 8.3 Substrate: 100 mg suc-AAPF-pNa is dissolved into 1 ml dimethyl sulfoxide (DMSO). 100 μl of this is diluted into 10 ml with Britton and Robinson buffer.

The substrate and protease solution is mixed and the absorbance is monitored at 405 nm as a function of time and ABS₄₀₅ nm/min. The temperature should be controlled (20-50° C. depending on protease). This is a measure of the protease activity in the sample.

Proteolytic Activity

In the context of this invention proteolytic activity is expressed in Kilo NOVO Protease Units (KNPU). The activity is determined relatively to an enzyme standard (SAVINASE_), and the determination is based on the digestion of a dimethyl casein (DMC) solution by the proteolytic enzyme at standard conditions, i.e. 50° C., pH 8.3, 9 min. reaction time, 3 min. measuring time. A folder AF 220/1 is available upon request to Novo Nordisk A/S, Denmark, which folder is hereby included by reference.

A GU is a Glycine Unit, defined as the proteolytic enzyme activity which, under standard conditions, during a 15-minutes' incubation at 40° C., with N-acetyl casein as substrate, produces an amount of NH₂-group equivalent to 1 mmole of glycine.

Enzyme activity can also be measured using the PNA assay, according to reaction with the soluble substrate succinyl-alanine-alanine-proline-phenyl-alanine-para-nitrophenol, which is described in the Journal of American Oil Chemists Society, Rothgeb, T. M., Goodlander, B. D., Garrison, P. H., and Smith, L. A., (1988).

Fermentation of PD498 Variants

Fermentation of PD498 variants in B. subtilis are performed at 30° C. on a rotary shaking table (300 r.p.m.) in 500 ml baffled Erlenmeyer flasks containing 100 ml BPX medium for 5 days. In order to make an e.g. 2 liter broth 20 Erlenmeyer flasks are fermented simultaneously.

Media

BPX: Composition (per liter)

Potato starch 100 g  Ground barley 50 g Soybean flour 20 g Na₂HPO₄ × 12 H₂O  9 g Pluronic 0.1 g  Sodium caseinate 10 g

The starch in the medium is liquefied with α-amylase and the medium is sterilized by heating at 120° C. for 45 minutes. After sterilization the pH of the medium is adjusted to 9 by addition of NaHCO₃ to 0.1 M.

Purification of PD498 Variants

Approximately 1.6 litres of PD498 variant fermentation broth are centrifuged at 5000 rpm for 35 minutes in 1 litre beakers. The supernatants are adjusted to pH 7.0 using 10% acetic acid and filtered on Seitz Supra S100 filter plates. The filtrates are concentrated-to approximately 400 ml using an Amicon CH2A UF unit equipped with an Amicon S1Y10 UF cartridge. The UF concentrate is centrifuged and filtered prior to absorption at room temperature on a Bacitracin affinity column at pH 7. The PD498 variant is eluted from the Bacitracin column at room temperature using 25% 2-propanol and 1 M sodium chloride in a buffer solution with 0.0 dimethylgutaric acid, 0.1 M boric acid and 0.002 M calcium chloride adjusted to pH 7.

The fractions with protease activity from the Bacitracin purification step are combined and applied to a 750 ml Sephadex G25 column (5 cm diameter) equilibrated with a buffer containing 0.01 dimethylglutaric acid, 0.1 M boric acid and 0.002 M calcium chloride adjusted to pH 6.0. Fractions with proteolytic activity from the Sephadex G25 column are combined and applied to a 150 ml CM Sepharose CL 6B cation exchange column (5 cm diameter) equilibrated with a buffer containing 0.01 M dimethylglutaric acid, 0.1 M boric acid, and 0.002 M calcium chloride adjusted to pH 6.0. The protease is eluted using a linear gradient of 0-0.5 M sodium chloride in 1 litres of the same buffer. Protease containing fractions from the CM Sepharose column are combined and filtered through a 2 μfilter.

Balb/C Mice IgG ELISA Procedure:

The antigen is diluted to 1 mg/ml in carbonate buffer.

100 ml is added to each well.

The plates are coated overnight at 4° C.

Unspecific adsorption is blocked by incubating each well for 1 hour at room temperature with 200 ml blocking buffer.

The plates are washed 3× with 300 ml washing buffer.

Unknown mouse sera are diluted in dilution buffer, typically 10×, 20× and 40×, or higher.

100 ml is added to each well.

Incubation is for 1 hour at room temperature.

Unbound material is removed by washing 3× with washing buffer.

The anti-Mouse IgG1 antibody is diluted 2000× in dilution buffer.

100 ml is added to each well.

Incubation is for 1 hour at room temperature.

Unbound material is removed by washing 3× with washing buffer.

Streptavidine is diluted 1000× in dilution buffer.

100 ml is added to each well.

Incubation is for 1 hour at room temperature.

Unbound material is removed by washing 3× with 300 ml washing buffer.

OPD (0.6 mg/ml) and H₂O₂ (0.4 ml/ml) is dissolved in citrate buffer.

100 ml is added to each well.

Incubation is for 10 minutes at room temperature.

The reaction is stopped by adding 100 ml H₂SO₄.

The plates are read at 492 nm with 620 nm as reference.

Immunisation of Mice

Balb C mice (20 grams) are immunized 10 times (intervals of 14 days) by subcutaneous injection of the modified or unmodified polypeptide in question, respectively by standard, procedures known in art.

EXAMPLES Example 1

Suitable Substitutions in PD498 for Addition of Amino Attachment Groups (—NH₂)

The 3D structure of parent PD498 was modeled as described above based on 59% sequence identity with Thermitase® (2tec.pdb).

The sequence of PD498 is (see SEQ ID NO. 2). PD498 residue numbering is used, 1-280.

The commands performed in Insight (BIOSYM) are shown in the command files makeKzone.bcl and makeKzone2.bcl below:

Conservative Substitutions:

makekzone.bcl

1 Delete Subset *

2 Color Molecule Atoms * Specified Specification 55,0,255

3 Zone Subset LYS :lys:NZ Static monomer/residue 10 Color_Subset 255,255,0

4 Zone Subset NTERM :1: N Static monomer/residue 10 Color_Subset 255,255,0

5 #NOTE: editnextline ACTSITE residues according to the protein

6 Zone Subset ACTSITE :39,72,226 Static monomer/residue 8 Color_Subset 255,255,0

7 Combine Subset ALLZONE Union LYS NTERM

8 Combine Subset ALLZONE Union ALLZONE ACTSITE

9 #NOTE: editnextline object name according to the protein

10 Combine Subset REST Difference PD498FINALMODEL ALLZONE

11 List Subset REST Atom Output_File restatom.list

12 List Subset REST monomer/residue Output_File restmole.list

13 Color Molecule Atoms ACTSITE Specified Specification 255,0,0

14 List Subset ACTSITE Atom Output_File actsiteatom.list

15 List Subset ACTSITE monomer/residue Output_File actsitemole.list

16 #

17 Zone Subset REST5A REST Static Monomer/Residue 5-Color_Subset

18 Combine Subset SUB5A Difference REST5A ACTSITE

19 Combine Subset SUB5B Difference SUB5A REST

20 Color Molecule Atoms SUB5B Specified Specification 255,255,255

21 List Subset SUB5B Atom Output_File sub5batom.list

22 List Subset SUB5B monomer/residue Output_File sub5bmole.list

23 #Now identify sites for lys→arg substitutions and continue with makezone2.bcl

24 #Use grep command to identify ARG in restatom.list, sub5batom.list & accsiteatom.list

Comments:

Lines 1-8: The subset ALLZONE is defined as those residues which are either within 10 Å of the free amino groups on lysines or the N-terminal, or within 8 Å of the catalytic triad residues 39, 72 and 226.

Line 10: The subset REST is defined as those residues not included in ALLZONE.

Lines 17-20: Subset SUB5B is defined as those residues in a 5 Å shell around REST, excluding residues within 8 Å of the catalytic residues.

Line 23-24: REST contains Arg62 and Arg169, SUB5B contains Arg51, Arg121, and Arg250. ACTSITE contains Arg103, but position 103 is within 8 Å from essential_catalytic residues, and thus not relevant.

The colour codes are: (255,0,255)=magenta, (255,255,0)yellow, (255,0,0) red, and (255, 255, 255)=white.

The substitutions R51K, R62K, R121K, R169K and R250K are identified in parent PD498 as suitable sites for mutagenesis. The residues are substituted below in section 2, and further analysis done:

Non-conservative Substitutions:

makeKzone2.bcl

1 #sourcefile makezone2.bcl Claus von der Osten 961128

2 #

3 #having scanned lists (grep arg command) and identified sites for lys→arg substitutions

4 #NOTE: editnextline object name according to protein

5 Copy Object -To_Clipboard -Displace PD498FINALMODEL newmodel

6 Biopolymer

7 #NOTE: editnextline object name according to protein

8 Blank Object On PD498FINALMODEL

9 #NOTE: editnextlines with lys→arg positions

10 Replace Residue newmodel:51 lys L

11 Replace Residue newmodel:62 lys L

12 Replace Residue newmodel:121 lys L

13 Replace Residue newmodel:169 lys L

14 Replace Residue newmodel:250 lys L

15 #

16 #Now repeat analysis done prior to arg→lys, now including introduced lysines

17 Color Molecule Atoms newmodel Specified Specification 255,0,255

18 Zone Subset LYSx newmodel:lys:NZ Static monomer/residue 10 Color_Subset 255,255,0

19 Zone Subset NTERMx newmodel:1:N Static monomer/residue 10 Color_Subset 255,255,0

20 #NOTE: editnextline ACTSITEx residues according to the protein

21 Zone Subset ACTSITEx newmodel:39,72,226 Static monomer/residue 8 Color_Subset 255,255,0

22 Combine Subset ALLZONEx Union LYSx NTERMx

23 Combine Subset ALLZONEx Union ALLZONEx ACTSITEx

24 Combine Subset RESTx Difference newmodel ALLZONEx

25 List Subset RESTx Atom Output_File restatom.list

26 List Subset RESTx monomer/residue Output_File restxmole.list

27 #

28 Color Molecule Atoms ACTSITEx Specified Specification 255,0,0

29 List Subset ACTSITEx Atom Output_File actsitexatom.list

30 List Subset ACTSITEx monomer/residue Output_File actsitexmole.list

31 #

32 #read restxatom.list or restxmole.list to identify sites for (not_arg)→lys subst. if needed

Comments:

Lines 1-15: Solvent exposed arginines in subsets REST and SUB5B are replaced by lysines. Solvent accessibilities are recalculated following arginine replacement.

Lines 16-23: The subset ALLZONEx is defined as those residues which are either within 10 Å of the free amino groups on Lysines (after replacement) or the N-terminal, or within 8 Å of the catalytic triad residues 39, 72 and 226.

Line 24-26: The subset RESTx is defined as those residues not included in ALLZONEx, i.e. residues which are still potential epitope contributors. of the residues in RESTx, the following are >5% exposed (see lists below): 6-7,9-12,43-45,65,87-88,209,211,216-221,262.

The following mutations are proposed in parent PD498: P6K, Y7K, S9K, A10K, Y11K, Q12K, D43K, Y44K, N45K, N65K, G87K, I88K, N209K, A211K, N216K, N217K, G218K, Y219K, S220K, Y221K, G262K. Relevant data for Example 1: Solvent accessibility data for PD498MODEL:

# PD498MODEL  Fri Nov 29 10:24 MET 1996 # residue area TRP_1 136.275711 SER_2 88.188095 PRO_3 15.458788 ASN_4 95.322319 ASP_5 4.903404 PRO_6 68.096909 TYR_7 93.333252 TYR_8 31.791576 SER_9 95.983139 ALA_10 77.983536 TYR_11 150.704727 GLN_12 26.983349 TYR_13 44.328232 GLY_14 3.200084 PRO_15 2.149547 GLN_16 61.385445 ASN_17 37.776707 THR_18 1.237873 SER_19 41.031750 THR_20 4.321402 PRO_21 16.658991 ALA_22 42.107288 ALA_23 0.000000 TRP_24 3.713619 ASP_25 82.645493 VAL_26 74.397812 THR_27 14.950654 ARG_28 110.606209 GLY_29 0.242063 SER_30 57.225292 SER_31 86.986198 THR_32 1.928865 GLN_33 42.008949 THR_34 0.502189 VAL_35 0.268693 ALA_36 0.000000 VAL_37 5.255383 LEU_38 1.550332 ASP_39 3.585718 SER_40 2.475746 GLY_41 4.329043 VAL_42 1.704864 ASP_43 25.889742 TYR_44 89.194855 ASN_45 109.981819 HIS_46 0.268693 PRO_47 66.580925 ASP_48 0.000000 LEU_49 0.770882 ALA_50 49.618046 ARG_51 218.751709 LYS_52 18.808538 VAL_53 39.937984 ILE_54 98.478104 LYS_55 103.612228 GLY_56 17.199390 TYR_57 67.719147 ASP_58 0.000000 PHE_59 40.291119 ILE_60 50.151962 ASP_61 70.078888 ARG_62 166.777557 ASP_63 35.892376 ASN_64 120.641953 ASN_65 64.982895 PRO_66 6.986028 MET_67 58.504269 ASP_68 28.668840 LEU_69 104.467468 ASN_70 78.460953 GLY_71 5.615932 HIS_72 43.158905 GLY_73 0.268693 THR_74 0.000000 HIS_75 0.484127 VAL_76 1.880854 ALA_77 0.000000 GLY_78 0.933982 THR_79 9.589676 VAL_80 0.000000 ALA_81 0.000000 ALA_82 0.000000 ASP_83 46.244987 THR_84 27.783333 ASN_85 75.924225 ASN_86 44.813908 GLY_87 50.453152 ILE_88 74.428070 GLY_89 4.115077 VAL_90 6.717335 ALA_91 2.872341 GLY_92 0.233495 MET_93 5.876057 ALA_94 0.000000 PRO_95 17.682203 ASP_96 83.431740 THR_97 1.506567 LYS_98 72.674973 ILE_99 4.251006 LEU_100 6.717335 ALA_101 0.806080 VAL_102 1.426676 ARG_103 2.662697 VAL_104 2.171855 LEU_105 18.808538 ASP_106 52.167435 ALA_107 52.905663 ASN_108 115.871315 GLY_109 30.943356 SER_110 57.933651 GLY_111 50.705326 SER_112 56.383320 LEU_113 71.312195 ASP_114 110.410919 SER_115 13.910152 ILE_116 22.570246 ALA_117 5.642561 SER_118 29.313131 GLY_119 0.000000 ILE_120 1.343467 ARG_121 118.391129 TYR_122 44.203033 ALA_123 0.000000 ALA_124 7.974043 ASP_125 83.851639 GLN_126 64.311974 GLY_127 36.812618 ALA_128 4.705107 LYS_129 90.886139 VAL_130 1.039576 LEU_131 2.149547 ASN_132 4.315227 LEU_133 1.880854 SER_134 3.563334 LEU_135 26.371397 GLY_136 59.151070 CYS_137 63.333755 GLU_138 111.553314 CYS_139 83.591461 ASN_140 80.757843 SER_141 25.899158 THR_142 99.889725 THR_143 73.323814 LEU_144 5.589301 LYS_145 94.708755 SER_146 72.636993 ALA_147 9.235920 VAL_148 1.612160 ASP_149 57.431465 TYR_150 106.352493 ALA_151 0.268693 TRP_152 43.133667 ASN_153 112.864975 LYS_154 110.009468 GLY_155 33.352180 ALA_156 3.493014 VAL_157 1.048144 VAL_158 2.043953 VAL_159 0.000000 ALA_160 0.537387 ALA_161 10.872165 ALA_162 7.823834 GLY_163 12.064573 ASN_164 81.183388 ASP_165 64.495300 ASN_166 83.457443 VAL_167 68.516815 SER_168 78.799652 ARG_169 116.937134 THR_170 57.275074 PHE_171 51.416462 GLN_172 18.934589 PRO_173 1.880854 ALA_174 6.522357 SER_175 26.184139 TYR_176 21.425076 PRO_177 85.613541 ASN_178 34.700817 ALA_179 0.268693 ILE_180 1.074774 ALA_181 3.761708 VAL_182 0.000000 GLY_183 2.149547 ALA_184 0.951118 ILE_185 0.806080 ASP_186 30.022263 SER_187 72.518509 ASN_188 117.128021 ASP_189 47.601345 ARG_190 150.050873 LYS_191 64.822807 ALA_192 2.686934 SER_193 96.223808 PHE_194 51.482613 SER_195 1.400973 ASN_196 4.148808 TYR_197 80.937309 GLY_198 10.747736 THR_199 93.221252 TRP_200 169.943604 VAL_201 15.280325 ASP_202 12.141763 VAL_203 0.268693 THR_204 3.409728 ALA_205 0.000000 PRO_206 0.000000 GLY_207 0.000000 VAL_208 37.137192 ASN_209 78.286270 ILE_210 9.404268 ALA_211 25.938599 SER_212 5.037172 THR_213 0.000000 VAL_214 22.301552 PRO_215 45.251030 ASN_216 131.014160 ASN_217 88.383461 GLY_218 21.226780 TYR_219 88.907570 SER_220 39.966541 TYR_221 166.037018 MET_222 50.951096 SER_223 54.435001 GLY_224 1.880854 THR_225 1.634468 SER_226 17.432346 MET_227 7.233279 ALA_228 0.000000 SER_229 0.000000 PRO_230 0.268693 HIS_231 2.680759 VAL_232 0.000000 ALA_233 0.000000 GLY_234 1.074774 LEU_235 11.500556 ALA_236 0.000000 ALA_237 0.000000 LEU_238 1.612160 LEU_239 0.000000 ALA_240 10.648088 SER_241 39.138004 GLN_242 71.056175 GLY_243 66.487144 LYS_244 43.256012 ASN_245 80.728127 ASN_246 34.859673 VAL_247 84.145645 GLN_248 51.819775 ILE_249 8.598188 ARG_250 35.055809 GLN_251 71.928093 ALA_252 0.000000 ILE_253 4.845899 GLU_254 13.344438 GLN_255 81.705254 THR_256 9.836061 ALA_257 2.810513 ASP_258 44.656136 LYS_259 113.071686 ILE_260 32.089527 SER_261 91.590103 GLY_262 26.450439 THR_263 38.308762 GLY_264 46.870056 THR_265 88.551804 ASN_266 34.698349 PHE_267 7.756911 LYS_268 103.212852 TYR_269 37.638382 GLY_270 0.000000 LYS_271 11.376978 ILE_272 2.885231 ASN_273 19.195255 SER_274 2.651736 ASN_275 38.177547 LYS_276 84.549576 ALA_277 1.074774 VAL_278 4.775503 ARG_279 162.693054 TYR_280 96.572929 CA_281 0.000000 CA_282 0.000000 CA_283 8.803203

Subset REST:

restmole.list

Subset REST:

PD498FINALMODEL:6-7,9-12,43-46,61-63,65,87-89,111-114,117-118,131,

PD498FINALMODEL:137-139,158-159,169-171,173-174,180-181,209,211,

PD498FINALMODEL:216-221,232-233,262, E282H

restatom.list

Subset REST:

PD498FINALMODEL:PRO 6:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:TYR 7:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:SER 9:N,CA,C,O,CB,OG

PD498FINALMODEL:ALA 10:N,CA,C,O,CB

PD498FINALMODEL:TYR 11:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:GLN 12:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:ASP 43:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:TYR

44:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:ASN 45:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:HIS

46:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

PD498FINALMODEL:ASP 61:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:ARG

62:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:ASP 63:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:ASN 65:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:GLY 87:N,CA,C,O

PD498FINALMODEL:ILE 88:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:GLY 89:N,CA,C,O

PD498FINALMODEL:GLY 111:N,CA,C,O

PD498FINALMODEL:SER 112:N,CA,C,O,CB,OG

PD498FINALMODEL:LEU 113:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ASP 114:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:ALA 117:N,CA,C,O,CB

PD498FINALMODEL:SER 118:N,CA,C,O,CB,OG

PD498FINALMODEL:LEU 131:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:CYS 137:N,CA,C,O,CB,SG

PD498FINALMODEL:GLU

138:N,CA,C,O,CB,CG,CD,OE1,OE2

PD498FINALMODEL:CYS 139:N,CA,C,O,CB,SG

PD498FINALMODEL:VAL 158:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:VAL 159:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ARG

169:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:THR 170:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:PHE

171:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

PD498FINALMODEL:PRO 173:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:ALA 174:N,CA,C,O,CB

PD498FINALMODEL:ILE 180:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:ALA 181:N,CA,C,O,CB

PD498FINALMODEL:ASN 209:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:ALA 211:N,CA,C,O,CB

PD498FINALMODEL:ASN 216:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:ASN 217:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:GLY 218:N,CA,C,O

PD498FINALMODEL:TYR

219:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:SER 220:N,CA,C,O,CB,OG

PD498FINALMODEL:TYR

221:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:VAL 232:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ALA 233:N,CA,C,O,CB

PD498FINALMODEL:GLY 262:N,CA,C,O

PD498FINALMODEL:CA E282H:CA

Subset SUB5B:

sub5bmole.list

Subset SUB5B:

PD498FINALMODEL:4-5,8,13-16,34-35,47-51,53,64,83,85-86,90-91,120-124,

PD498FINALMODEL:128-130,140-141,143-144,147-148,151-152,156-157,

PD498FINALMODEL:165,167-168,172,175-176,178-179,196,200-205,208,

PD498FINALMODEL:234-237,250,253-254,260-261,263-267,272,E281H,

PD498FINALMODEL:E283H

sub5batom.list

Subset SUB5B:

PD498FINALMODEL:ASN.4:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:ASP 5:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:TYR

8:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:TYR

13:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:GLY 14:N,CA,C,O

PD498FINALMODEL:PRO 15:N,CA,CD,C,O, CB,CG

PD498FINALMODEL:GLN 16:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:THR 34:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:VAL 35:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:PRO 47:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:ASP 48:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:LEU 49:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ALA 50:N,CA,C,O,CB

PD498FINALMODEL:ARG

51:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:VAL 53:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ASN 64:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:ASP 83:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:ASN 85:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:ASN 86:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:VAL 90:N,CA, C,O,CB,CG1,CG2

PD498FINALMODEL:ALA 91:N,CA,C,O,CB

PD498FINALMODEL:ILE 120:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:ARG

121:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:TYR

122:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:ALA 123:N,CA,C,O,CB

PD498FINALMODEL:ALA 124:N,CA,C,O,CB

PD498FINALMODEL:ALA 128:N,CA,C,O,CB

PD498FINALMODEL:LYS 129:N,CA,C,O,CB,CG,CD,CE,NZ

PD498FINALMODEL:VAL 130:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ASN 140:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:SER 141:N,CA,C,O,CB,OG

PD498FINALMODEL:THR 143:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:LEU 144:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ALA 147:N,CA,C,O,CB

PD498FINALMODEL:VAL 148:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ALA 151:N,CA,C,O,CB

PD498FINALMODEL:TRP

52:N,CA,C,O,CB,CG,CD1,CD2,NE1,CE2,CE3, CZ2,CZ3,CH2

PD498FINALMODEL:ALA 156:N,CA,C,O,CB

PD498FINALMODEL:VAL 157:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ASP 165:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:VAL 167:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:SER 168:N,CA,C,O,CB,OG

PD498FINALMODEL:GLN

172:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:SER 175:N,CA,C,O,CB,OG

PD498FINALMODEL:TYR

176:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:ASN 178:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:ALA 179:N,CA,C,O,CB

PD498FINALMODEL:ASN 196:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:TRP

200:N,CA,C,O,CB,CG,CD1,CD2,NE1,CE2,CE3, CZ2,CZ3,CH2

PD498FINALMODEL:VAL 201:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ASP 202:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:VAL 203:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:THR 204:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:ALA 205:N,CA,C,O,CB

PD498FINALMODEL:VAL 208:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:GLY 234:N,CA,C,O

PD498FINALMODEL:LEU 235:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ALA 236:N,CA,C,O,CB

PD498FINALMODEL:ALA 237:N,CA,C,O,CB

PD498FINALMODEL:ARG

250:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:ILE 253:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:GLU

254:N,CA,C,O,CB,CG,CD,OE1,OE2

PD498FINALMODEL:ILE 260:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:SER 261:N,CA,C,O,CB,OG

PD498FINALMODEL:THR 263:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:GLY 264:N,CA,C,O

PD498FINALMODEL:THR 265:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:ASN 266:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:PHE

267:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

PD498FINALMODEL:ILE 272:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:CA E281H:CA

PD498FINALMODEL:CA E283H:NA

Subset ACTSITE:

actsitemole.list

Subset ACTSITE:

PD498FINALMODEL:36-42,57-60,66-80,100-110,115-116,119,132-136,160-164,

PD498FINALMODEL:182-184,194,206-207,210,212-215,222-231

actsiteatom.list

Subset ACTSITE:

PD498FINALMODEL:ALA 36:N,CA,C,O,CB

PD498FINALMODEL:VAL 37:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:LEU 38:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ASP 39:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:SER 40:N,CA,C,O,CB,OG

PD498FINALMODEL:GLY 41:N,CA,C,O

PD498FINALMODEL:VAL 42:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:TYR

57:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:ASP 58:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:PHE

59:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

PD498FINALMODEL:ILE 60:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:PRO 66:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:MET 67:N,CA,C,O,CB,CG,SD,CE

PD498FINALMODEL:ASP 68:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:LEU 69:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ASN 70:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:GLY 71:N,CA,C,O

PD498FINALMODEL:HIS

72:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

PD498FINALMODEL:GLY 73:N,CA,C,O

PD498FINALMODEL:THR 74:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:HIS

75:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

PD498FINALMODEL:VAL 76:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ALA 77:N,CA,C,O,CB

PD498FINALMODEL:GLY 78:N,CA,C,O

PD498FINALMODEL:THR 79:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:VAL 80:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:LEU 100:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ALA 101:N,CA,C,O,CB

PD498FINALMODEL:VAL 102:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ARG

103:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:VAL 104:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:LEU 105:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ASP 106:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:ALA 107:N,CA,C,O,CB

PD498FINALMODEL:ASN 108:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:GLY 109:N,CA,C,O

PD498FINALMODEL:SER 110:N,CA,C,O,CB,OG

PD498FINALMODEL:SER 115:N,CA,C,O,CB,OG

PD498FINALMODEL:ILE 116:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:GLY 119:N,CA,C,O

PD498FINALMODEL:ASN 132:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:LEU 133:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:SER 134:N,CA,C,O,CB,OG

PD498FINALMODEL:LEU 135:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:GLY 136:N,CA,C,O

PD498FINALMODEL:ALA 160:N,CA,C,O,CB

PD498FINALMODEL:ALA 161:N,CA,C,O,CB

PD498FINALMODEL:ALA 162:N,CA,C,O,CB

PD498FINALMODEL:GLY 163:N,CA,C,O

PD498FINALMODEL:ASN 164:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:VAL 182:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:GLY 183:N,CA,C,O

PD498FINALMODEL:ALA 184:N,CA,C,O,CB

PD498FINALMODEL:PHE

194:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

PD498FINALMODEL:PRO 206:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:GLY 207:N,CA,C,O

PD498FINALMODEL:ILE 210:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:SER 212:N,CA,C,O,CB,OG

PD498FINALMODEL:THR 213:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:VAL 214:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:PRO 215:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:MET 222:N,CA,C,O,CB,CG,SD,CE

PD498FINALMODEL:SER 223:N,CA,C,O,CB,OG

PD498FINALMODEL:GLY 224:N,CA,C,O

PD498FINALMODEL:THR 225:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:SER 226:N,CA,C,O,CB,OG

PD498FINALMODEL:MET 227:N,CA,C,O,CB,CG,SD,CE

PD498FINALMODEL:ALA 228:N,CA,C,O,CB

PD498FINALMODEL:SER 229:N,CA,C,O,CB,OG

PD498FINALMODEL:PRO 230:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:HIS

231:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

Subset RESTx:

restxmole.list

Subset RESTx:

NEWMODEL:6-7,9-12,43-46,65,87-89,131,173,209,211,216-221,232-233,

NEWMODEL:262,E282H

restxatom.list

Subset RESTx:

NEWMODEL:PRO 6:N,CA,CD,C,O,CB,CG

NEWMODEL:TYR 7:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

NEWMODEL:SER 9:N,CA,C,O,CB,OG

NEWMODEL:ALA 10:N,CA,C,O,CB

NEWMODEL:TYR 11:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

NEWMODEL:GLN 12:N,CA,C,O,CB,CG,CD,OE1,NE2

NEWMODEL:ASP 43:N,CA,C,O,CB,CG,OD1,OD2

NEWMODEL:TYR 44:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

NEWMODEL:ASN 45:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:HIS 46:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

NEWMODEL:ASN 65:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:GLY 87:N,CA,C,O

NEWMODEL:ILE 88:N,CA,C,O,CB,CG1,CG2,CD1

NEWMODEL:GLY 89:N,CA,C,O

NEWMODEL:LEU 131:N,CA,C,O,CB,CG,CD1,CD2

NEWMODEL:PRO 173:N,CA,CD,C,O,CB,CG

NEWMODEL:ASN 209:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:ALA 211:N,CA,C,O,CB

NEWMODEL:ASN 216:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:ASN 217:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:GLY 218:N,CA,C,O

NEWMODEL:TYR 219:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

NEWMODEL:SER 220:N,CA,C,O,CB,OG

NEWMODEL:TYR 221:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

NEWMODEL:VAL 232:N,CA,C,O,CB,CG1,CG2

NEWMODEL:ALA 233:N,CA,C,O,CB

NEWMODEL:GLY 262:N,CA,C,O

NEWMODEL:CA E282H:CA

Example 2

Suitable Substitutions in SAVINASE® for Addition of Amino Attachment Groups (—NH₂)

The known X-ray structure of SAVINASE® was used to find where suitable amino attachment groups may is added (Betzel et al, (1992), J. Mol. Biol. 223,p 427-445).

The 3D structure of, SAVINASE® is available in the Brookhaven Databank as 1svn.pbd. A related subtilisin is available as 1st3.pdb.

The sequence of SAVINASE® is shown in SEQ ID NO. 3 The sequence numbering used is that of subtilisin BPN′, SAVINASE® having deletions relative to BPN′ at positions: 36, 56, 158-159 and 163-164. The active site residues (functional site) are D32,H64 and S221.

The commands performed in Insight (BIOSYM) are shown in the command files makeKzone.bcl and makeKzone2.bcl below:

Conservative Substitutions:

makekzone.bcl

Delete Subset *

Color Molecule Atoms * Specified Specification 255,0,255

Zone Subset LYS :lys:NZ Static monomer/residue 10 Color_Subset 255,255,0

Zone Subset NTERM :e1:N Static monomer/residue 10 Color_Subset 255,255,0

#NOTE: editnextline ACTSITE residues according to the protein

Zone Subset ACTSITE :e32,e64,e221 Static monomer/residue 8

Color_Subset 255,255,0

Combine Subset ALLZONE Union LYS NTERM

Combine Subset ALLZONE Union ALLZONE ACTSITE

#NOTE: editnextline object name according to the protein

Combine Subset REST Difference SAVI8 ALLZONE

List Subset REST Atom Output_File restatom.list

List Subset REST monomer/residue Output_File restmole.list

Color Molecule Atoms ACTSITE Specified Specification 255,0,0

List Subset ACTSITE Atom Output_File actsiteatom.list

List Subset ACTSITE monomer/residue Output_File

actsitemole.list

#

Zone Subset REST5A REST Static Monomer/Residue 5-Color_Subset

Combine Subset SUB5A Difference REST5A ACTSITE

Combine Subset SUB5B Difference SUB5A REST

Color Molecule Atoms SUB5B Specified Specification 255,255,255

List Subset SUB5B Atom Output_File sub5batom.list

List Subset SUB5B monomer/residue Output_File sub5bmole.list

#Now identify sites for lys→arg substitutions and continue with makezone2.bcl

#Use grep command to identify ARG in restatom.list,

sub5batom.list & accsiteatom.list

Comments: 4

In this case of SAVINASE® REST contains the Arginines Arg10, Arg170 and Arg 186, and SUB5B contains Arg19, Arg45, Arg145 and Arg247.

These residues are all solvent exposed. The substitutions R10K, R19K, R45K, R145K, R170K, R186K and R247K are identified in SAVINASE® as sites for mutagenesis within the scope of this invention. The residues are substituted below in section 2, and further analysis done. The subset ACTSITE contains Lys94.

The substitution K94R is a mutation removing Lysine as attachment group close to the active site.

Non-conservative Substitutions:

makeKzone2.bcl

#sourcefile makezone2.bcl Claus von der Osten 961128

#

#having scanned lists (grep arg command) and identified sites for lys→arg substitutions

#NOTE: editnextline object name according to protein

Copy Object -To_Clipboard -Displace SAVE8 newmodel Biopolymer

#NOTE: editnextline object name according to protein Blank Object On SAVI8

#NOTE: editnextlines with lys→arg positions

Replace Residue newmodel:e10 lys L

Replace Residue newmodel:e170 lys L

Replace Residue newmodel:e186 lys L

Replace Residue newmodel:e19 lys L

Replace Residue newmodel:e45 lys L

Replace Residue newmodel:e145 lys L

Replace Residue newmodel:e241 lys L

#Now repeat analysis done prior to arg→lys, now including

introduced lysines

Color Molecule Atoms newmodel Specified Specification 255,0,255

Zone Subset LYSx newmodel:lys:NZ Static monomer/residue 10

Color_Subset 255,255,0

Zone Subset NTERMx newmodel:e1:N Static monomer/residue 10

Color_Subset 255,255,0

#NOTE: editnextline ACTSITEx residues according to the protein

Zone Subset ACTSITEx newmodel:e32,e64,e221 Static

monomer/residue 8 Color_Subset 255,255,0

Combine Subset ALLZONEx Union LYSx NTERMx

Combine Subset ALLZONEx Union ALLZONEx ACTSITEx

Combine Subset RESTx Difference newmodel ALLZONEx

List Subset RESTx Atom Output_File restxatom.list

List Subset RESTx monomer/residue Output_File restxmole.list

Color Molecule Atoms ACTSITEx Specified Specification 255,0,0

List Subset ACTSITEx Atom Output_File actsitexatom.list

List Subset ACTSITEx monomer/residue Output_File

actsitexmole.list

#

#read restxatom.list or restxmole.list to identify sites for (not_arg)→lys subst. if needed

Comments:

Of the residues in RESTx, the following are >5% exposed (see lists below): 5,14,22,38-40,42,75-76,82,86,103-105,108,133-135,137,140,173,204,206,211-213,215-216,269. The following mutations are proposed in SAVINASE®: P5K, P14K, T22K, T38K, H39K, P40K, L42K, L75K, N76K, L82K, P86K, S103K, V104K, S105K, A108K, A133K, T134K, L135K, Q137K, N140K, N173K, N204K, Q206K, G211K, S212K, T213K, A215K, S216K, N269K. Relevant data for Example 2:

Solvent Accessibility Data for SAVINASE®:

# SAVI8NOH2O  Fri Nov 29 13:32:07 MET 1996 # residue area ALA_1 118.362808 GLN_2 49.422764 SER_3 61.982887 VAL_4 71.620255 PRO_5 21.737535 TRP_6 58.718731 GLY_7 4.328117 ILE_8 6.664074 SER_9 60.175900 ARG_10 70.928963 VAL_11 2.686934 GLN_12 72.839996 ALA_13 0.000000 PRO_14 52.308453 ALA_15 38.300892 ALA_16 0.000000 HIS_17 41.826324 ASN_18 136.376602 ARG_19 105.678642 GLY_20 48.231510 LEU_21 17.196377 THR_22 36.781742 GLY_23 0.000000 SER_24 64.151276 GLY_25 50.269905 VAL_26 4.030401 LYS_27 54.239555 VAL_28 0.000000 ALA_29 0.000000 VAL_30 3.572827 LEU_31 0.233495 ASP_32 1.074774 THR_33 1.973557 GLY_34 3.638052 ILE_35 8.044439 SER_36 8.514903 THR_37 122.598907 HIS_38 18.834011 PRO_39 76.570526 ASP_40 0.000000 LEU_41 19.684013 ASN_42 88.870216 ILE_43 56.117710 ARG_44 110.647194 GLY_45 26.935413 GLY_46 35.515778 ALA_47 21.495472 SER_48 34.876190 PHE_49 52.647541 VAL_50 23.364208 PRO_51 110.408752 GLY_52 80.282906 GLU_53 43.033707 PRO_54 124.444336 SER_55 60.284889 THR_56 47.103241 GLN_57 120.803505 ASP_58 12.784743 GLY_59 61.742443 ASN_60 56.760231 GLY_61 1.576962 HIS_62 38.590118 GLY_63 0.000000 THR_64 0.537387 HIS_65 0.968253 VAL_66 1.612160 ALA_67 0.00000G GLY_68 2.801945 THR_69 9.074596 ILE_70 0.000000 ALA_71 4.577205 ALA_72 0.000000 LEU_73 47.290039 ASN_74 102.187248 ASN_75 60.210400 SER_76 84.614494 ILE_77 66.098572 GLY_78 17.979534 VAL_79 5.642561 LEU_80 13.025185 GLY_81 0.000000 VAL_82 0.268693 ALA_83 0.000000 PRO_84 18.193810 SER_85 56.839039 ALA_86 13.075745 GLU_87 37.011765 LEU_88 2.149547 TYR_89 30.633518 ALA_90 1.343467 VAL_91 0.779450 LYS_92 5.862781 VAL_93 0.466991 LEU_94 10.747736 GLY_95 8.707102 ALA_96 41.414677 SER_97 96.066040 GLY_98 33.374485 SER_99 67.664116 GLY_100 35.571117 SER_101 54.096992 VAL_102 52.695324 SER_103 62.929684 SER_104 8.683097 ILE_105 15.852910 ALA_106 14.509443 GLN_107 94.463066 GLY_108 0.000000 LEU_109 0.537387 GLU_110 63.227707 TRP_111 55.500740 ALA_112 0.502189 GLY_113 11.908267 ASN_114 107.208527 ASN_115 78.811234 GLY_116 41.453194 MET_117 9.634291 HIS_118 54.022118 VAL_119 5.105174 ALA_120 0.268693 ASN_121 0.233495 LEU_122 0.537387 SER_123 4.004620 LEU_124 21.927265 GLY_125 55.952454 SER_126 40.241180 PRO_127 107.409439 SER_128 57.988609 PRO_129 85.021118 SER_130 20.460915 ALA_131 57.404362 THR_132 74.438805 LEU_133 12.091203 GLU_134 73.382019 GLN_135 114.870010 ALA_136 2.122917 VAL_137 1.074774 ASN_138 55.622704 SER_139 29.174965 ALA_140 0.268693 THR_141 27.962946 SER_142 87.263145 ARG_143 88.201218 GLY_144 38.477882 VAL_145 2.079151 LEU_146 13.703363 VAL_147 2.690253 VAL_148 1.074774 ALA_149 0.000000 ALA_150 4.356600 SER_151 0.000000 GLY_152 12.628590 ASN_153 84.248703 SER_154 77.662354 GLY_155 25.409861 ALA_156 38.074570 GLY_157 40.493744 SER_158 53.915291 ILE_159 4.352278 SER_160 12.458543 TYR_161 29.670284 PRO_162 4.030401 ALA_163 0.968253 ARG_164 84.059120 TYR_165 28.641129 ALA_166 68.193314 ASN_167 61.686481 ALA_168 0.537387 MET_169 0.586837 ALA_170 0.000000 VAL_171 0.000000 GLY_172 0.000000 ALA_173 0.933982 THR_174 3.013133 ASP_175 34.551376 GLN_176 96.873039 ASN_177 98.664368 ASN_178 41.197159 ASN_179 60.263512 ARG_180 64.416336 ALA_181 7.254722 SER_182 91.590881 PHE_183 52.126518 SER_184 2.101459 GLN_185 15.736279 TYR_186 44.287792 GLY_187 5.114592 ALA_188 69.406563 GLY_189 36.926083 LEU_190 16.511177 ASP_191 7.705349 ILE_192 0.268693 VAL_193 4.299094 ALA_194 0.000000 PRO_195 0.806080 GLY_196 0.000000 VAL_197 25.257177 ASN_198 82.177422 VAL_199 10.747736 GLN_200 80.374527 SER_201 2.008755 THR_202 0.000000 TYR_203 80.679886 PRO_204 34.632195 GLY_205 74.536827 SER_206 74.964920 THR_207 57.070065 TYR_208 82.895500 ALA_209 22.838940 SER_210 69.045639 LEU_211 49.708279 ASN_212 86.905457 GLY_213 2.686934 THR_214 4.669909 SER_215 15.225292 MET_216 7.261287 ALA_217 0.000000 THR_218 0.000000 PRO_219 0.806080 HIS_220 2.662697 VAL_221 0.268693 ALA_222 0.000000 GLY_223 0.000000 ALA_224 7.206634 ALA_225 1.039576 ALA_226 0.268693 LEU_227 1.074774 VAL_228 1.541764 LYS_229 39.262505 GLN_230 54.501614 LYS_231 81.154129 ASN_232 30.004124 PRO_233 91.917931 SER_234 102.856705 TRP_235 64.639481 SER_236 51.797619 ASN_237 24.866917 VAL_238 78.458466 GLN_239 73.981461 ILE_240 14.474245 ARG_241 41.242931 ASN_242 64.644814 HIS_243 50.671440 LEU_244 5.127482 LYS_245 48.820000 ASN_246 115.264534 THR_247 22.205376 ALA_248 16.415077 THR_249 60.503101 SER_250 74.511597 LEU_251 48.861599 GLY_252 39.124340 SER_253 49.811481 THR_254 88.421982 ASN_255 72.490181 LEU_256 54.835758 TYR_257 38.798912 GLY_258 3.620916 SER_259 35.017368 GLY_260 0.537387 LEU_261 8.598188 VAL_262 4.519700 ASN_263 16.763659 ALA_264 3.413124 GLU_265 37.942276 ALA_266 15.871746 ALA_267 3.947115 THR_268 2.475746 ARG_269 176.743362 ION_270 0.000000 ION_271 5.197493

Subset REST:

restmole.list

Subset REST:

SAVI8:E5-E15,E17-E18,E22,E38-E40,E42-E43,E73-E76,E82-E86,E103-E105,

SAVI8:E108-E109,E111-E112,E115-E116,E122,E128-E144,E149-E150,E156-E157,

SAVI8:E160-E162,E165-E168,E170-E171,E173,E180-E188,E190-E192,E200,

SAVI8:E203-E204,E206,E211-E213,E215-E216,E227-E230,E255-E259,E261-E262,

SAVI8:E267-E269

restatom.list

Subset REST:

SAVI8:PRO E5:N,CD,CA,CG,CB,C,O

SAVI8:TRP E6:N,CA,CD2,CE2,NE1,CD1,CG,CE3,CZ3,CH2,CZ2,CB,C,O

SAVI8:GLY E7:N,CA,C,O

SAVI8:ILE E8:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:SER E9:N,CA,OG,CB,C,O

SAVI8:ARG E10:N,CA,NH2,NH1,CZ,NE,CD,CG,CB,C,O

SAVI8:VAL E11:N,CA,CG2,CG1,CB,C,O

SAVI8:GLN E12:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:ALA E13:N,CA,CB,C,O

SAVI8:PRO E14:N,CD,CA,CG,CB,C,O

SAVI8:ALA E15:N,CA,CB,C,O

SAVI8:HIS E17:N,CA,CD2,NE2,CE1,ND1,CG,CB,C,O

SAVI8:ASN E18:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:THR E22:N,CA,CG2,OG1,CB,C,O

SAVI8:THR E38:N,CA,CG2,OG1,CB,C,O

SAVI8:HIS E39:N,CA,CD2,NE2,CE1,ND1,CG,CB,C,O

SAVI8:PRO E40:N,CD,CA,CG,CB,C,O

SAVI8:LEU E42:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:ASN E43:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:ALA E73:N,CA,CB,C,O

SAVI8:ALA E74:N,CA,CB,C,O

SAVI8:LEU E75:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:ASN E76:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:LEU E82:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:GLY E83:N,CA,C,O

SAVI8:VAL E84:N,CA,CG2,CG1,CB,C,O

SAVI8:ALA E85:N,CA,CB,C,O

SAVI8:PRO E86:N,CD,CA,CG,CB,C,O

SAVI8:SER E103:N,CA,OG,CB,C,O

SAVI8:VAL E104:N,CA,CG2,CG1,CB,C,O

SAVI8:SER E105:N,CA,OG,CB,C,O

SAVI8:ALA E108:N,CA,CB,C,O

SAVI8:GLN E109:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:LEU E111:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:GLU E112:N,CA,OE2,OE1,CD,CG,CB,C,O

SAVI8:GLY E115:N,CA,C,O

SAVI8:ASN E116:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:ALA E122:N,CA,CB,C,O

SAVI8:SER E128:N,CA,OG,CB,C,O

SAVI8:PRO E129:N,CD,CA,CG,CB,C,O

SAVI8:SER E130:N,CA,OG,CB,C,O

SAVI8:PRO E131:N,CD,CA,CG,CB,C,O

SAVI8:SER E132:N,CA,OG,CB,C,O

SAVI8:ALA E133:N,CA,CB,C,O

SAVI8:THR E134:N,CA,CG2,OG1,CB,C,O

SAVI8:LEU E135:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:GLU E136:N,CA,OE2,OE1,CD,CG,CB,C,O

SAVI8:GLN E137:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:ALA E138:N,CA,CB,C,O

SAVI8:VAL E139:N,CA,CG2,CG1,CB,C,O

SAVI8:ASN E140:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:SER E141:N,CA,OG,CB,C,O

SAVI8:ALA E142:N,CA,CB,C,O

SAVI8:THR E143:N,CA,CG2,OG1,CB,C,O

SAVI8:SER E144:N,CA,OG,CB,C,O

SAVI8:VAL E149:N,CA,CG2,CG1,CB,C,O

SAVI8:VAL E150:N,CA,CG2,CG1,CB,C,O

SAVI8:SER E156:N,CA,OG,CB,C,O

SAVI8:GLY E157:N,CA,C,O

SAVI8:ALA E160:N,CA,CB,C,O

SAVI8:GLY E161:N,CA,C,O

SAVI8:SER E162:N,CA,OG,CB,C,O

SAVI8:ILE E165:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:SER E166:N,CA,OG,CB,C,O

SAVI8:TYR E167:N,CA,OH,CZ,CD2,CE2,CE1,CD1,CG,CB,C,O

SAVI8:PRO E168:N,CD,CA,CG,CB,C,O

SAVI8:ARG E170:N,CA,NH2,NH1,CZ,NE,CD,CG,CB,C,O

SAVI8:TYR E171:N,CA,OH,CZ,CD2,CE2,CE1,CD1,CG,CB,C,O

SAVI8:ASN E173:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:THR E180:N,CA,CG2,OG1,CB,C,O

SAVI8:ASP E181:N,CA,OD2,OD1,CG,CB,C,O

SAVI8:GLN E182:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:ASN E183:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:ASN E184:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:ASN E185:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:ARG E186:N,CA,NH2,NH1,CZ,NE,CD,CG,CB,C,O

SAVI8:ALA E187:N,CA,CB,C,O

SAVI8:SER E188:N,CA,OG,CB,C,O

SAVI8:SER E190:N,CA,OG,CB,C,O

SAVI8:GLN E191:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:TYR E192:N,CA,OH,CZ,CD2,CE2,CE1,CD1₁,CG,CB,C,O

SAVI8:ALA E200:N,CA,CB,C,O

SAVI8:VAL E203:N,CA,CG2,CG1,CB,C,O

SAVI8:ASN E204:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:GLN E206:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:GLY E211:N,CA,C,O

SAVI8:SER E212:N,CA,OG,CB,C,O

SAVI8:THR E213:N,CA,CG2,OG1,CB,C,O

SAVI8:ALA E215:N,CA,CB,C,O

SAVI8:SER E216:N,CA,OG,CB,C,O

SAVI8:VAL E227:N,CA,CG2,CG1,CB,C,O

SAVI8:ALA E228:N,CA,CB,C,O

SAVI8:GLY E229:N,CA,C,O

SAVI8:ALA E230:N,CA,CB,C,O

SAVI8:THR E255:N,CA,CG2,OG1,CB,C,O

SAVI8:SER E256:N,CA,OG,CB,C,O

SAVI8:LEU E257:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:GLY E258:N,CA,C,O

SAVI8:SER E259:N,CA,OG,CB,C,O

SAVI8:ASN E261:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:LEU E262:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:LEU E267:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:VAL E268:N,CA,CG2,CG1,CB,C,O

SAVI8:ASN E269:N,CA,ND2,OD1,CG,CB,C,O

Subset SUB5B:

sub5bmole.list

Subset SUB5B:

SAVI8:E2-E4,E16,E19-E21,E23-E24,E28,E37,E41,E44-E45, E77-E81,E87-E88,

SAVI8:E90,E113-E114,E117-E118,E120-E121,E145-E148,E169,E172,E174-E176,

SAVI8:E193-E196,E198-E199,E214,E231-E234,E236,E243,E247,E250,E253-E254,

SAVI8:E260,E263-E266,E270-E273,M276H-M277H

sub5batom.list

Subset SUB5B:

SAVI8:GLN E2:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:SER E3:N,CA,OG,CB,C,O

SAVI8:VAL E4:N,CA,CG2,CG1,CB,C,O

SAVI8:ALA E16:N,CA,CB,C,O

SAVI8:ARG E19:N,CA,NH2,NH1,CZ,NE,CD,CG,CB,C,O

SAVI8:GLY E20:N,CA,C,O

SAVI8:LEU E21:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:GLY.E23:N,CA,C,O

SAVI8:SER E24:N,CA,OG,CB,C,O

SAVI8:VAL E28:N,CA,CG2,CG1,CB,C,O

SAVI8:SER E37:N,CA,OG,CB,C,O

SAVI8:ASP E41:N,CA,OD2,OD1,CG,CB,C,O

SAVI8:ILE E44:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:ARG E45:N,CA,NH2,NH1,CZ,NE,CD,CG,CB,C,O

SAVI8:ASN E77:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:SER E78:N,CA,OG,CB,C,O

SAVI8:ILE E79:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:GLY E80:N,CA,C,O

SAVI8:VAL E81:N,CA,CG2,CG1,CB,C,O

SAVI8:SER E87:N,CA,OG,CB,C,O

SAVI8:ALA E88:N,CA,CB,C,O

SAVI8:LEU E90:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:TRP E113:N,CA,CD2,CE2,NE1,CD1,CG,CE3,CZ3,CH2,CZ2,CB,C,O

SAVI8:ALA E114:N,CA,CB,C,O

SAVI8:ASN E117:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:GLY E118:N,CA,C,O

SAVI8:HIS E120:N,CA,CD2,NE2,CE1,ND1,CG,CB,C,O

SAVI8:VAL E121:N,CA,CG2,CG1,CB,C,O

SAVI8:ARG E145:N,CA,NH2,NH1,CZ,NE,CD,CG,CB,C,O

SAVI8:GLY E146:N,CA,C,O

SAVI8:VAL E147:N,CA,CG2,CG1,CB,C,O

SAVI8:LEU E148:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:ALA E169:N,CA,CB,C,O

SAVI8:ALA E172:N,CA,CB,C,O

SAVI8:ALA E174:N,CA,CB,C,O

SAVI8:MET E175:N,CA,CE,SD,CG,CB,C,O

SAVI8:ALA E176:N,CA,CB,C,O

SAVI8:GLY E193:N,CA,C,O

SAVI8:ALA E194:N,CA,CB,C,O

SAVI8:GLY E195:N,CA,C,O

SAVI8:LEU E196:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:ILE E198:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:VAL E199:N,CA,CG2,CG1,CB,C,O

SAVI8:TYR E214:N,CA,OH,CZ,CD2,CE2,CE1,CD1,CG,CB,C,O

SAVI8:ALA E231:N,CA,CB,C,O

SAVI8:ALA E232:N,CA,CB,C,O

SAVI8:LEU E233:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:VAL E234:N,CA,CG2,CG1,CB,C,O

SAVI8:GLN E236:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:ASN E243:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:ARG E247:N,CA,NH2,NH1,CZ,NE,CD,CG,CB,C,O

SAVI8:LEU E250:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:THR E253:N,CA,CG2,OG1,CB,C,O

SAVI8:ALA E254:N,CA,CB,C,O

SAVI8:THR E260:N,CA,CG2,OG1,CB,C,O

SAVI8:TYR E263:N,CA,OH,CZ,CD2,CE2,CE1,CD1,CG,CB,C,O

SAVI8:GLY E264:N,CA,C,O

SAVI8:SER E265:N,CA,OG,CB,C,O

SAVI8:GLY E266:N,CA,C,O

SAVI8:ALA E270:N,CA,CB,C,O

SAVI8:GLU E271:N,CA,OE2,OE1,CD,CG,CB,C,O

SAVI8:ALA E272:N,CA,CB,C,O

SAVI8:ALA E273:N,CA,CB,C,O

SAVI8:ION M276H:CA

SAVI8:ION M277H:CA

Subset ACTSITE:

actsitemole.list

Subset ACTSITE:

SAVI8:E29-E35,E48-E51,E54,E58-E72,E91-E102,E106-E107,E110,E123-E127,

SAVI8: E151-E155,E177-E179,E189,E201-E202,E205,E207-E210,E217-E226

actsiteatom.list

Subset ACTSITE:

SAVI8:ALA E29:N,CA,CB,C,O

SAVI8:VAL E30:N,CA,CG2,CG1,CB,C,O

SAVI8:LEU E31:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:ASP E32:N,CA,OD2,OD1,CG,CB,C,O

SAVI8:THR E33:N,CA,CG2,OG1,CB,C,O

SAVI8:GLY E34:N,CA,C,O

SAVI8:ILE E35:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:ALA E48:N,CA,CB,C,O

SAVI8:SER E49:N,CA,OG,CB,C,O

SAVI8:PHE E50:N,CA,CD2,CE2,CZ,CE1,CD1,CG,CB,C,O

SAVI8:VAL E51:N,CA,CG2,CG1,CB,C,O

SAVI8:GLU E54:N,CA,OE2,OE1,CD,CG,CB,C,O

SAVI8:THR E58:N,CA,CG2,OG1,CB,C,O

SAVI8:GLN E59:N,CA,NE2,OE1,CD,CG,CB,C,O

SAVI8:ASP E60:N,CA,OD2,OD1,CG,CB,C,O

SAVI8:GLY E61:N,CA,C,O

SAVI8:ASN E62:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:GLY E63:N,CA,C,O

SAVI8:HIS E64:N,CA,CD2,NE2,CE1,ND1,CG,CB,C,O

SAVI8:GLY E65:N,CA,C,O

SAVI8:THR E66:N,CA,CG2,OG1,CB,C,O

SAVI8:HIS E67:N,CA,CD2,NE2,CE1,ND1,CG,CB,C,O

SAVI8:VAL E68:N,CA,CG2,CG1,CB,C,O

SAVI8:ALA E69:N,CA,CB,C,O

SAVI8:GLY E70:N,CA,C,O

SAVI8:THR E71:N,CA,CG2,OG1,CB,C,O

SAVI8:ILE E72:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:TYR E91:N,CA,OH,CZ,CD2,CE2,CE1,CD1,CG,CB,C,O

SAVI8:ALA E92:N,CA,CB,C,O

SAVI8:VAL E93:N,CA,CG2,CG1,CB,C,O

SAVI8:LYS E94:N,CA,NZ,CE,CD,CG,CB,C,O

SAVI8:VAL E95:N,CA,CG2,CG1,CB,C,O

SAVI8:LEU E96:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:GLY E97:N,CA,C,O

SAVI8:ALA E98:N,CA,CB,C,O

SAVI8:SER E99:N,CA,OG,CB,C,O

SAVI8:GLY E100:N,CA,C,O

SAVI8:SER E101:N,CA,OG,CB,C,O

SAVI8:GLY E102:N,CA,C,O

SAVI8:SER E106:N,CA,OG,CB,C,O

SAVI8:ILE E107:N,CA,CD1,CG1,CB,CG2,C,O

SAVI8:GLY E110:N,CA,C,O

SAVI8:ASN E123:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:LEU E124:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:SER E125:N,CA,OG,CB,C,O

SAVI8:LEU E126:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:GLY E127:N,CA,C,O

SAVI8:ALA E151:N,CA,CB,C,O

SAVI8:ALA E152:N,CA,CB,C,O

SAVI8:SER E153:N,CA,OG,CB,C,O

SAVI8:GLY E154:N,CA,C,O

SAVI8:ASN E155:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:VAL E177:N,CA,CG2,CG1,CB,C,O

SAVI8:GLY E178:N,CA,C,O

SAVI8:ALA E179:N,CA,CB,C,O

SAVI8:PHE E189:N,CA,CD2,CE2,CZ, CE1,CD1,CG,CB,C,O

SAVI8:PRO E201:N,CD,CA,CG,CB,C,O

SAVI8:GLY E202:N,CA,C,O

SAVI8:VAL E205:N,CA,CG2,CG1,CB,C,O

SAVI8:SER E207:N,CA,OG,CB,C,O

SAVI8:THR E208:N,CA,CG2,OG1,CB,C,O

SAVI8:TYR E209:N,CA,OH,CZ,CD2,CE2,CE1,CD1,CG,CB,C,O

SAVI8:PRO E210:N,CD,CA,CG,CB,C,O

SAVI8:LEU E217:N,CA,CD2,CD1,CG,CB,C,O

SAVI8:ASN E218:N,CA,ND2,OD1,CG,CB,C,O

SAVI8:GLY E219:N,CA,C,O

SAVI8:THR E220:N,CA,CG2,OG1,CB,C,O

SAVI8:SER E221:N,CA,OG,CB,C,O

SAVI8:MET E222:N,CA,CE,SD,CG,CB,C,O

SAVI8:ALA E223:N,CA,CB,C,O

SAVI8:THR E224:N,CA,CG2,OG1,CB,C,O

SAVI8:PRO E225:N,CD,CA,CG,CB,C,O

SAVI8:HIS E226:N,CA,CD2,NE2,CE1,ND1,CG,CB,C,O

Subset RESTx:

restxmole.list

Subset RESTx:

NEWMODEL:E5,E13-E14,E22,E38-E40,E42,E73-E76,E82-E86,E103-E105,

NEWMODEL:E108,E122,E133-E135,E137-E140,E149-E150,E173,E204,E206,

NEWMODEL:E211-E213,E215-E216,E227-E229,E258,E269

restxatom.list

Subset RESTx:

NEWMODEL:PRO E5:N,CD,CA,CG,CB,C,O

NEWMODEL:ALA E13:N,CA,CB,C,O

NEWMODEL:PRO E14:N,CD,CA,CG,CB,C,O

NEWMODEL:THR E22:N,CA,CG2,OG1,CB,C,O

NEWMODEL:THR E38:N,CA,CG2,OG1,CB,C,O

NEWMODEL:HIS E39:N,CA,CD2,NE2,CE1,ND1,CG,CB,C,O

NEWMODEL:PRO E40:N,CD,CA,CG,CB,C,O

NEWMODEL:LEU E42:N,CA,CD2,CD1,CG,CB,C,O

NEWMODEL:ALA E73:N,CA,CB,C,O

NEWMODEL:ALA E74:N,CA,CB,C,O

NEWMODEL:LEU E75:N,CA,CD2,CD1,CG,CB,C,O

NEWMODEL:ASN E76:N,CA,ND2,OD1,CG,CB,C,O

NEWMODEL:LEU E82:N,CA,CD2,CD1,CG,CB,C,O

NEWMODEL:GLY E83:N,CA,C,O

NEWMODEL:VAL E84:N,CA,CG2,CG1,CB,C,O

NEWMODEL:ALA E85:N,CA,CB,C,O

NEWMODEL:PRO E86:N,CD,CA,CG,CB,C,O

NEWMODEL:SER E103:N,CA,OG,CB,C,O

NEWMODEL:VAL E104:N,CA,CG2,CG1,CB,C,O

NEWMODEL:SER E105:N,CA,OG,CB,C,O

NEWMODEL:ALA E108:N,CA,CB,C,O

NEWMODEL:ALA E122:N,CA,CB,C,O

NEWMODEL:ALA E133:N,CA,CB,C,O

NEWMODEL:THR E134:N,CA,CG2,OG1,CB,C,O

NEWMODEL:LEU E135:N,CA,CD2,CD1,CG,CB,C,O

NEWMODEL:GLN E137:N,CA,NE2,OE1,CD,CG,CB,C,O

NEWMODEL:ALA E138:N,CA,CB,C,O

NEWMODEL:VAL E139:N,CA,CG2,CG1,CB,C,O

NEWMODEL:ASN E140:N,CA,ND2,CD1,CG,CB,C,O

NEWMODEL:VAL E149:N,CA,CG2,CG1,CB,C,O

NEWMODEL:VAL E150:N,CA,CG2,CG1,CB,C,O

NEWMODEL:ASN E173:N,CA,ND2,OD1,CG,CB,C,O

NEWMODEL:ASN E204:N,CA,ND2,OD1,CG,CB,C,O

NEWMODEL:GLN E206:N,CA,NE2,OE1,CD,CG,CB,C,O

NEWMODEL:GLY E211:N,CA,C,O

NEWMODEL:SER E212:N,CA,OG,CB,C,O

NEWMODEL:THR E213:N,CA,CG2,OG1,CB,C,O

NEWMODEL:ALA E215:N,CA,CB,C,O

NEWMODEL:SER E216:N,CA,OG,CB,C,O

NEWMODEL:VAL E227:N,CA,CG2,CG1,CB,C,O

NEWMODEL:ALA E228:N,CA,CB,C,O

NEWMODEL:GLY E229:N,CA,C,O

NEWMODEL:GLY E258:N,CA,CO

NEWMODEL:ASN E269:N,CA,ND2,OD1,CG,CB,C,O

Example 3

Suitable Substitutions in PD498 for Addition of Carboxylic Acid Attachment Groups (—COOH)

The 3D structure of PD498 was modeled as described in Example 1. Suitable locations for addition of carboxylic attachment groups (Aspartatic acids and Glutamic acids) were found as follows. The procedure described in Example 1 was followed. The commands performed in Insight (BIOSYM) are shown in the command files makeDEzone.bcl and makeDEzone2.bcl below:

Conservative Substutitions:

makeDEzone.bcl

Delete Subset *

Color Molecule Atoms * Specified Specification255,0,255

Zone Subset ASP :asp:od* Static monomer/residue 10 Color_Subset 255,255,0

Zone Subset GLU :glu:oe* Static monomer/residue 10 Color_Subset 255,255,0

#NOTE: editnextline C-terminal residue number according to the protein

Zone Subset CTERM :280:0 Static monomer/residue 10 Color_Subset 255,255,0

#NOTE: editnextline ACTSITE residues according to the protein

Zone Subset ACTSITE :39,72,226 Static monomer/residue 8

Color_Subset 255,255,0

Combine Subset ALLZONE Union ASP GLU

Combine Subset ALLZONE Union ALLZONE CTERM

Combine Subset ALLZONE Union ALLZONE ACTSITE

#NOTE: editnextline object name according to the protein

Combine Subset REST Difference PD498FINALMODEL ALLZONE

List Subset REST Atom output_File restatom.list

List Subset REST monomer/residue Output_File restmole.list

Color Molecule Atoms ACTSITE Specified Specification 255,0,0

List Subset ACTSITE Atom Output_File actsiteatom.list

List Subset ACTSITE monomer/residue Output_File actsitemole.list

#

Zone Subset REST5A REST Static Monomer/Residue 5- Color_Subset

Combine Subset SUB5A Difference REST5A ACTSITE

Combine Subset SUB5B Difference SUB5A REST

Color Molecule Atoms SUB5B Specified Specification 255,255,255

List Subset SUB5B Atom Output_File sub5batom.list

List Subset SUB5B monomer/residue Output_File sub5bmole.list

#Now identify sites for asn→asp & gln→glu substitutions and . . .

#continue with makezone2.bcl.

#Use grep command to identify asn/gln in restatom.list . . .

#sub5batom.list & accsiteatom.list

Comments:

The subset REST contains Gln33 and Asn245, SUB5B contains Gln12, Gln126, Asn209, Gln242, Asn246, Gln248 and Asn266, all of which are solvent exposed.

The substitutions Q12E or Q12D, Q33E or Q33D, Q126E or Q126D, N209D or N209E, Q242E or Q242D, N245D or N245E, N246D or N246E, Q248E or Q248D and N266D or N266E are identified in PD498 as sites for mutagenesis within the scope of this invention. Residues are substituted below in section 2, and further analysis done:

Non-conservative Substitutions:

makeDEzone2.bcl

#sourcefile makezone2.bcl Claus von der Osten 961128

#

#having scanned lists (grep gln/asn command) and identified

sites for . . .

#asn→asp & gln→glu substitutions

#NOTE: editnextline object name according to protein

Copy Object -To_Clipboard -Displace PD498FINALMODEL newmodel Biopolymer

#NOTE: editnextline object name according to protein

Blank Object On PD498FINALMODEL

#NOTE: editnextlines with asn→asp & gln→glu positions

Replace Residue newmodel:33 glu L

Replace Residue newmodel:245 asp L

Replace Residue newmodel:12 glu L

Replace Residue newmodel:126 glu L

Replace Residue newmodel:209 asp L

Replace Residue newmodel:242 glu L

Replace Residue newmodel:246 asp L

Replace Residue newmodel:248 glu L

Replace Residue newmodel:266 asp L

#

#Now repeat analysis done prior to asn→asp & gln→glu, . . .

#now including introduced asp & glu

Color Molecule Atoms newmodel Specified Specification 255,0,255

Zone Subset ASPx newmodel:Asp:od* Static monomer/residue 10

Color_Subset 255,255,0

Zone Subset GLUx newmodel:glu:oe* Static monomer/residue 10

Color_Subset 255,255,0

#NOTE: editnextline C-terminal residue number according to the protein

Zone Subset CTERMx newmodel:280: O Static monomer/residue 10

Color_Subset 255,255,0

#NOTE. editnextline ACTSITEx residues according to the protein

Zone Subset ACTSITEx newmodel:39,72,226 Static monomer/residue

8 Color_Subset 255,255,0

Combine Subset ALLZONEx Union ASPx GLUx

Combine Subset ALLZONEx Union ALLZONEx CTERMX

Combine Subset ALLZONEx Union ALLZONEx ACTSITEx

Combine Subset RESTx Difference newmodel ALLZONEx

List Subset RESTx Atom output_File restxatom.list

List Subset RESTx monomer/residue Output_File restxmole.list

#

Color Molecule Atoms ACTSITEx Specified Specification 255,0,0

List Subset ACTSITEx Atom Output_File actsitexatom.list

List Subset ACTSITEx monomer/residue Output_File actsitexmole.list

#

#read restxatom.list or restxmole.list to identify sites for

(not_gluasp)→gluasp . . .

#subst. if needed

Comments:

The subset RESTx contains only two residues: A233 and G234, none of which are solvent exposed. No further mutagenesis is required to obtain complete protection of the surface. However, it may be necessary to remove some of the reactive carboxylic groups in the active site region to ensure access to the active site of PD498. Acidic residues within the subset ACTSITE are: D39, D58, D68 and D106. Of these only the two latter are solvent exposed and D39 is a functional residue. The mutations D68N, D68Q, D106N and D106Q were found suitable according to the present invention.

Relevant data for Example 3: Solvent accessibility data for PD498MODEL: see Example 1 above.

Subset REST:

restmole.list

Subset REST:

PD498FINALMODEL:10-11,33-35,54-55,129-130,221,233-234,236,240,243,

PD498FINALMODEL:245,262,264-265

restatom.list

Subset REST:

PD498FINALMODEL:ALA 10:N,CA,C,O,CB

PD498FINALMODEL:TYR 11:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:GLN 33:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:THR 34:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:VAL 35:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ILE 54:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:LYS 55:N,CA,C,O,CB,CG,CD,CE,NZ

PD498FINALMODEL:LYS 129:N,CA,C,O,CB,CG,CD,CE,NZ

PD498FINALMODEL:VAL 130:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:TYR 221:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:ALA 233:N,CA,C,O,CB

PD498FINALMODEL:GLY 234:N,CA,C,O

PD498FINALMODEL:ALA 236:N,CA,C,O,CB

PD498FINALMODEL:ALA 240:N,CA,C,O,CB

PD498FINALMODEL:GLY 243:N,CA,C,O

PD498FINALMODEL:ASN 245:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:GLY 262:N,CA,C,O

PD498FINALMODEL:GLY 264:N,CA,C,O

PD498FINALMODEL:THR 265:N,CA,C,O,CB,OG1,CG2

Subset SUB5B:

sub5bmole.list

Subset SUB5B:

PD498FINALMODEL:6-9,12-13,3-1-32,51-53, 56,81,93-94,97-99,122,126-128,

PD498FINALMODEL:131,155-157,159,197-199,209,211,219-220,232,235,

PD498FINALMODEL:237-239,241-242,244,246-249, 253,260-261,263,266-268

sub5batom.list

Subset SUB5B:

PD498FINALMODEL:PRO 6:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:TYR 7:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:TYR 8:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:SER 9:N,CA,C,O,CB,OG

PD498FINALMODEL:GLN 12:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:TYR 13:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:SER 31:N,CA,C,O,CB,OG

PD498FINALMODEL:THR 32:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:ARG 51:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:LYS 52:N,CA,C,O,CB,CG,CD,CE,NZ

PD498FINALMODEL:VAL 53:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:GLY 56:N,CA,C,O

PD498FINALMODEL:ALA 81:N,CA,C,O,CB

PD498FINALMODEL:MET 93:N,CA,C,O,CB,CG,SD,CE

PD498FINALMODEL:ALA 94:N,CA,C,O,CB

PD498FINALMODEL:THR 97:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:LYS 98:N,CA,C,O,CB,CG,CD,CE,NZ

PD498FINALMODEL:ILE 99:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:TYR 122:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:GLN 126:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:GLY 127:N,CA,C,O

PD498FINALMODEL:ALA 128:N,CA,C,O,CB

PD498FINALMODEL:LEU 131:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:GLY 155:N,CA,C,O

PD498FINALMODEL:ALA 156:N,CA,C,O,CB

PD498FINALMODEL:VAL 157:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:VAL 159:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:TYR 197:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:GLY 198:N,CA,C,O

PD498FINALMODEL:THR 199:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:ASN 209:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:ALA 211:N,CA,C,O,CB

PD498FINALMODEL:TYR 219:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:SER 220:N,CA,C,O,CB,OG

PD498FINALMODEL:VAL 232:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:LEU 235:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ALA 237:N,CA,C,O,CB

PD498FINALMODEL:LEU 238:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:LEU 239:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:SER 241:N,CA,C,O,CB,OG

PD498FINALMODEL:GLN 242:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:LYS 244:N,CA,C,O,CB,CG,CD,CE,NZ

PD498FINALMODEL:ASN 246:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:VAL 247:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:GLN 248:N,CA,C,O,CB,CG,CD,OE1,NE2

PD498FINALMODEL:ILE 249:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:ILE 253:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:ILE 260:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:SER 261:N,CA,C,O,CB,OG

PD498FINALMODEL:THR 263:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:ASN 266:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:PHE 267:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

PD498FINALMODEL:LYS 268:N,CA,C,O,CB,CG,CD,CE,NZ

Subset ACTSITE:

actsitemole.list

Subset ACTSITE:

PD498FINALMODEL:36-42,57-60,66-80,100-110,115-116,119,132-136,160-164,

PD498FINALMODEL:182-184,194,206-207,210,212-215,222-231

actsiteatom.list

Subset ACTSITE:

PD498FINALMODEL:ALA 36:N,CA,C,O,CB

PD498FINALMODEL:VAL 37:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:LEU 38:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ASP 39:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:SER 40:N,CA,C,O,CB,OG

PD498FINALMODEL:GLY 41:N,CA,C,O

PD498FINALMODEL:VAL 42:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:TYR

57:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

PD498FINALMODEL:ASP 58:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:PHE

59:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

PD498FINALMODEL:ILE 60:N,CA,C,O,CB,CG1,CG2,CD1

PD498FINALMODEL:PRO 66:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:MET 67:N,CA,C,O,CB,CG,SD,CE

PD498FINALMODEL:ASP 68:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:LEU 69:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ASN 70:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:GLY 71:N,CA,C,O

PD498FINALMODEL:HIS 72:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

PD498FINALMODEL:GLY 73:N,CA,C,O

PD498FINALMODEL:THR 74:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:HIS 75:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

PD498FINALMODEL:VAL 76:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ALA 77:N,CA,C,O,CB

PD498FINALMODEL:GLY 78:N,CA,C,O

PD498FINALMODEL:THR 79:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:VAL 80:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:LEU 100:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ALA 101:N,CA,C,O,CB

PD498FINALMODEL:VAL 102:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:ARG 103:N,CA,C,O,CB,

CG,CD,NE,CZ,NH1,NH2

PD498FINALMODEL:VAL 104:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:LEU 105:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:ASP 106:N,CA,C,O,CB,CG,OD1,OD2

PD498FINALMODEL:ALA 107:N,CA,C,O,CB

PD498FINALMODEL:ASN 108:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:GLY 109:N,CA,C,O

PD498FINALMODEL:SER 110:N,CA,C,O,CB,OG

PD498FINALMODEL:SER 115:N,CA,C,O,CB,OG

PD498FINALMODEL:ILE 116:N,CA,C,O,CB,

CG1,CG2,CD1

PD498FINALMODEL:GLY 119:N,CA,C,O

PD498FINALMODEL:ASN 132:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:LEU 133:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:SER 134:N,CA,C,O,CB,OG

PD498FINALMODEL:LEU 135:N,CA,C,O,CB,CG,CD1,CD2

PD498FINALMODEL:GLY 136:N,CA,C,O

PD498FINALMODEL:ALA 160:N,CA,C,O,CB

PD498FINALMODEL:ALA 161:N,CA,C,O,CB

PD498FINALMODEL:ALA 162:N,CA,C,O,CB

PD498FINALMODEL:GLY 163:N,CA,C,O

PD498FINALMODEL:ASN 164:N,CA,C,O,CB,CG,OD1,ND2

PD498FINALMODEL:VAL 182:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:GLY 183:N,CA,C,O

PD498FINALMODEL:ALA 184:N,CA,C,O,CB

PD498FINALMODEL:PHE 194:N,CA,C,O,CB,

CG,CD1,CD2,CE1,CE2,CZ

PD498FINALMODEL:PRO 206:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:GLY 207:N,CA,C,O

PD498FINALMODEL:ILE 210:N,CA,C,O,CB,

CG1,CG2,CD1

PD498FINALMODEL:SER 212:N,CA,C,O,CB,OG

PD498FINALMODEL:THR 213:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:VAL 214:N,CA,C,O,CB,CG1,CG2

PD498FINALMODEL:PRO 215:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:MET 222:N,CA,C,O,CB,CG,SD,CE

PD498FINALMODEL:SER 223:N,CA,C,O,CB,OG

PD498FINALMODEL:GLY 224:N,CA,C,O

PD498FINALMODEL:THR 225:N,CA,C,O,CB,OG1,CG2

PD498FINALMODEL:SER 226:N,CA,C,O,CB,OG

PD498FINALMODEL:MET 227:N,CA,C,O,CB,CG,SD,CE

PD498FINALMODEL:ALA 228:N,CA,C,O,CB

PD498FINALMODEL:SER 229:N,CA,C,O,CB,OG

PD498FINALMODEL:PRO 230:N,CA,CD,C,O,CB,CG

PD498FINALMODEL:HIS 231:N,CA,C,O,CB,

CG,ND1,CD2,CE1,NE2

Subset RESTx:

restxmole.list

Subset RESTX:

NEWMODEL:233-234

restxatom.list

Subset RESTX:

NEWMODEL:ALA 233:N,CA,C,O,CB

NEWMODEL:GLY 234:N,CA,C,O

Example 4

Suitable Substitutions in the Arthromyces Ramosus Peroxidase for Addition of Carboxylic Acid Attachment Groups (—COOH)

Suitable locations for addition of carboxylic attachment groups (Aspartatic acids and Glutamic acids) in a non-hydrolytic enzyme, Arthromyces ramosus peroxidase were found as follows.

The 3D structure of this oxido-reductase is available in the Brookhaven Databank as 1arp.pdb. This A. ramosus peroxidase contains 344 amino acid residues. The first eight residues are not visible in the X-ray structure: QGPGGGGG, and N143 is glycosylated. The procedure described in Example 1 was followed.

The amino acid sequence of Arthromyces ramosus Peroxidase (E.C.1.11.1.7) is shown in SEQ ID NO 4.

The commands performed in Insight (BIOSYM) are shown in the command files makeDEzone.bcl and makeDEzone2.bcl below. The C-terminal residue is P344, the ACTSITE is defined as the heme group and the two histidines coordinating it (H56 & H184).

Conservative Substitutions:

makeDEzone.bcl

Delete Subset *

Color Molecule Atoms * Specified Specification 255,0,255

Zone Subset ASP :asp:od* Static monomer/residue 10 Color_Subset 255,255,0

Zone Subset GLU :glu:oe* Static monomer/residue 10 Color_Subset 255,255,0

#NOTE: editnextline C-terminal residue number according to the

40 protein

Zone Subset CTERM :344:0 Static monomer/residue 10 Color_Subset 255,255,0

#NOTE: editnextline ACTSITE residues according to the protein

Zone Subset ACTSITE :HEM,56,184 Static monomer/residue 8

Color_Subset 255,255,0

Combine Subset ALLZONE Union ASP GLU

Combine Subset ALLZONE Union ALLZONE CTERM

Combine Subset ALLZONE Union ALLZONE ACTSITE

#NOTE: editnextline object name according to the protein

Combine Subset REST Difference ARP ALLZONE

List Subset REST Atom Output_File restatom. list

List Subset REST monomer/residue Output_File restmole.list

Color Molecule Atoms ACTSITE Specified Specification 255,0,0

List Subset ACTSITE Atom Output_File actsiteatom.list

List Subset ACTSITE monomer/residue output File

actsitemole.list

#

Zone Subset REST5A REST Static Monomer/Residue 5- Color_Subset

Combine Subset SUB5A Difference REST5A ACTSITE

Combine Subset SUB5B Difference SUB5A REST

Color Molecule Atoms SUB5B Specified Specification 255,255,255

List Subset SUB5B Atom Output_File sub5batom.list

List Subset SUB5B monomer/residue Output_File sub5bmole.list

#Now identify sites for asn→asp & gln→glu substitutions and . . .

#continue with makezone2.bcl.

#Use grep command to identify asn/gln in restatom.list

#sub5batom.list & accsiteatom.list

Comments:

The subset REST contains Gln70, and SUB5B contains Gln34, Asn128, Asn303 all of which are solvent exposed. The substitutions Q34E or Q34D, Q70E or Q70D, N128D or N128E and N303D or N303E are identified in A. ramosus peroxidase as sites for mutagenesis. Residues are substituted below and further analysis done:

Non-conservative Substitutions:

makeDEzone2.bcl

#sourcefile makezone2.bcl Claus von der Osten 961128

#

#having scanned lists (grep gln/asn command) and identified sites for . . .

#asn→asp & gln→glu substitutions

#NOTE: editnextline object name according to protein

Copy Object -To_Clipboard -Displace ARP newmodel Biopolymer

#NOTE: editnextline object name according to protein Blank Object On ARP

#NOTE: editnextlines with asn→asp & gln→glu positions

Replace Residue newmodel:34 glu L

Replace Residue newmodel:70 glu L

Replace Residue newmodel:128 asp L

Replace Residue newmodel:303 asp L

#Now repeat analysis done prior to asn→asp & gln→glu, . . .

#now including introduced asp & glu

Color Molecule Atoms newmodel Specified Specification 255,0,255

Zone Subset ASPx newmodel:asp:od* Static monomer/residue 10

Color_Subset 255,255,0

Zone Subset GLUx newmodel:glu:oe* Static monomer/residue 10

Color_Subset 255,255,0

#NOTE: editnextline C-terminal residue number according to the protein

Zone Subset CTERMX newmodel:344:0 Static monomer/residue 10

Color_Subset 255,255,0

#NOTE: editnextline ACTSITEx residues according to the protein

Zone Subset ACTSITEx newmodel:HEM,56,184 Static monomer/residue

8 Color_Subset 255,255,0

Combine Subset ALLZONEx Union ASPx GLUx

Combine Subset ALLZONEx Union ALLZONEx CTERMx

Combine Subset ALLZONEx Union ALLZONEx ACTSITEx

Combine Subset RESTX Difference newmodel ALLZONEx

List Subset RESTx Atom Output_File restxatom.list

List Subset RESTX monomer/residue Output_File restxmole.list

#

Color Molecule Atoms ACTSITEx Specified Specification 255,0,0

List Subset ACTSITEx Atom Output_File actsitexatom.list

List Subset ACTSITEx monomer/residue Output_File

actsitexmole.list

#

#read restxatom.list or restxmole.list to identify sites for (not_gluasp)→gluasp . . .

#subst. if needed

Comments:

The subset RESTX contains only four residues: S9, S334, G335 and P336, all of which are >5% solvent exposed. The mutations S9D, S9E, S334D, S334E, G335D, G335E, P336D and P336E are proposed in A. ramosus peroxidase. Acidic residues within the subset ACTSITE are: E44, D57, D77, E87, E176, D179, E190, D202, D209, D246 and the N-terminal carboxylic acid on P344. Of these only E44, D77, E176, D179, E190, D209, D246 and the N-terminal carboxylic acid on P344 are solvent exposed. Suitable sites for mutations are E44Q, D77N, E176Q, D179N, E190Q, D209N and D246N. D246N and D246E are risky mutations due to D246's importance for binding of heme.

The N-terminal 8 residues were not included in the calculations above, as they do not appear in the structure. None of these 8 residues, QGPGGGG, contain carboxylic groups. The following variants are proposed as possible mutations to enable attachment to this region: Q1E, Q1, G2E, G2D, P3E, P3D, 45 G4E, G4D, G5E, G5D, G6E, G6D, G7E, G7D, G8E, G8D.

Relevant Data for Example 4:

Solvent accessibility data for A. ramosus peroxidase (Note: as the first eight residues are missing in the X-ray structure, the residue numbers printed in the accessibility list below are 8 lower than those used elsewhere for residue numbering.

# ARP  Thu Jan 30 15:39:05 MET # residue area SER_1 143.698257 VAL_2 54.879990 THR_3 86.932701 CYS_4 8.303715 PRO_5 126.854782 GLY_6 53.771488 GLY_7 48.137802 GLN_8 62.288475 SER_9 79.932549 THR_10 16.299215 SER_11 81.928642 ASN_12 51.432678 SER_13 81.993019 GLN_14 92.344009 CYS_15 0.000000 CYS_16 32.317432 VAL_17 54.067810 TRP_18 6.451035 PHE_19 25.852070 ASP_20 79.033997 VAL_21 0.268693 LEU_22 22.032858 ASP_23 90.111404 ASP_24 43.99324G LEU_25 1.074774 GLN_26 25.589321 THR_27 82.698059 ASN_28 96.600883 PHE_29 32.375275 TYR_30 5.898365 GLN_31 103.380585 GLY_32 40.042034 SER_33 46.789322 LYS_34 87.161873 CYS_35 12.827215 GLU_36 51.582657 SER_37 16.378180 PRO_38 33.560043 VAL_39 6.448641 ARG_40 7.068311 LYS_41 15.291286 ILE_42 1.612160 LEU_43 1.880854 ARG_44 16.906845 ILE_45 0.000000 VAL_46 2.312647 PHE_47 2.955627 HIS_48 20.392527 ASP_49 4.238116 ALA_50 0.510757 ILE_51 1.576962 GLY_52 2.858601 PHE_53 48.633503 SER_54 8.973248 PRO_55 58.822315 ALA_56 59.782852 LEU_57 46.483955 THR_58 86.744827 ALA_59 89.515816 ALA_60 81.163239 GLY_61 70.119019 GLN_62 112.635498 PHE_63 93.522354 GLY_64 2.742587 GLY_65 13.379636 GLY_66 22.722847 GLY_67 0.000000 ALA_68 0.268693 ASP_69 12.074840 GLY_70 0.700486 SER_71 0.000000 ILE_72 0.000000 ILE_73 0.000000 ALA_74 17.304443 HIS_75 41.071186 SER_76 20.000793 ASN_77 120.855316 ILE_78 66.574982 GLU_79 2.334954 LEU_80 41.329689 ALA_81 77.370575 PHE_82 38.758774 PRO_83 131.946289 ALA_84 34.893864 ASN_85 5.457000 GLY_86 43.364151 GLY_87 51.561348 LEU_88 0.242063 THR_89 73.343575 ASP_90 130.139389 THR_91 17.863211 ILE_92 0.268693 GLU_93 92.210396 ALA_94 35.445068 LEU_95 1.343467 ARG_96 31.175611 ALA_97 44.650192 VAL_98 17.698566 GLY_99 1.471369 ILE_100 62.441463 ASN_101 107.139748 HIS_102 46.952496 GLY_103 46.559296 VAL_104 11.342628 SER_105 15.225677 PHE_106 6.422011 GLY_107 3.426864 ASP_108 10.740790 LEU_109 0.268693 ILE_110 1.880854 GLN_111 31.867456 PHE_112 0.000000 ALA_113 0.000000 THR_114 3.656114 ALA_115 8.299393 VAL_116 0.268693 GLY_117 0.268693 MET_118 3.761708 SER_119 14.536770 ASN_120 25.928799 CYS_121 0.537387 PRO_122 29.798336 GLY_123 33.080013 SER_124 17.115562 PRO_125 36.908714 ARG_126 108.274727 LEU_127 21.238588 GLU_128 53.742313 PHE_129 3.761708 LEU_130 12.928699 THR_131 10.414591 GLY_132 47.266495 ARG_133 12.247048 SER_134 63.047237 ASN_135 31.403708 SER_136 97.999619 SER_137 28.505201 GLN_138 102.845520 PRO_139 49.691917 SER_140 9.423104 PRO_141 25.724171 PRO_142 80.706665 SER_143 105.318176 LEU_144 20.154398 ILE_145 41.288322 PRO_146 10.462679 GLY_147 19.803421 PRO_148 18.130360 GLY_149 47.391853 ASN_150 60.248917 THR_151 87.887985 VAL_152 13.870322 THR_153 74.664734 ALA_154 45.251106 ILE_155 2.686934 LEU_156 28.720940 ASP_157 110.081253 ARG_158 31.228874 MET_159 1.612160 GLY_160 38.223858 ASP_161 46.293152 ALA_162 9.877204 GLY_163 34.267326 PHE_164 11.057570 SER_165 51.158882 PRO_166 62.767738 ASP_167 75.164917 GLU_168 43.334976 VAL_169 6.365355 VAL_170 2.955627 ASP_171 7.004863 LEU_172 1.880854 LEU_173 3.197691 ALA_174 0.000000 ALA_175 1.074774 HIS_176 0.502189 SER_177 0.806080 LEU_178 3.197691 ALA_179 3.337480 SER_180 0.466991 GLN_181 2.122917 GLU_182 40.996552 GLY_183 62.098671 LEU_184 23.954853 ASN_185 15.918136 SER_186 95.185318 ALA_187 59.075272 ILE_188 27.675419 PHE_189 102.799423 ARG_190 55.265549 SER_191 6.986028 PRO_192 2.686934 LEU_193 12.321225 ASP_194 2.127163 SER_195 33.556419 THR_196 33.049286 PRO_197 20.874798 GLN_198 65.729698 VAL_199 31.705818 PHE_200 4.753195 ASP_201 13.744506 THR_202 1.612160 GLN_203 16.081930 PHE_204 2.581340 TYR_205 1.880854 ILE_206 9.356181 GLU_207 0.735684 THR_208 10.685907 LEU_209 9.672962 LEU_210 2.955627 LYS_211 77.176834 GLY_212 40.968609 THR_213 78.718216 THR_214 21.738384 GLN_215 77.622299 PRO_216 25.441587 GLY_217 8.320850 PRO_218 96.972305 SER_219 64.627823 LEU_220 85.732414 GLY_221 27.361111 PHE_222 134.620178 ALA_223 3.873014 GLU_224 12.141763 GLU_225 65.129868 LEU_226 76.105843 SER_227 0.268693 PRO_228 7.017754 PHE_229 0.000000 PRO_230 47.827423 GLY_231 23.790522 GLU_232 6.643466 PHE_233 6.713862 ARG_234 18.012030 MET_235 4.598188 ARG_236 91.415581 SER_237 1.982125 ASP_238 6.246871 ALA_239 12.897283 LEU_240 76.820526 LEU_241 3.224321 ALA_242 1.400973 ARG_243 77.207176 ASP_244 36.207306 SER_245 104.023796 ARG_246 121.852341 THR_247 2.955627 ALA_248 4.810700 CYS_249 47.331306 ARG_250 62.062778 TRP_251 2.418241 GLN_252 5.554953 SER_253 38.284832 MET_254 1.124224 THR_255 0.000000 SER_256 53.758987 SER_257 37.276134 ASN_258 44.381340 GLU_259 149.565140 VAL_260 57.500389 MET_261 2.679314 GLY_262 10.175152 GLN_263 107.458916 ARG_264 36.402130 TYR_265 0.233495 ARG_266 91.179619 ALA_267 53.708500 ALA_268 6.504294 MET_269 17.122011 ALA_270 22.455158 LYS_271 73.386177 MET_272 3.959508 SER_273 15.043281 VAL_274 23.887930 LEU_275 17.196379 GLY_276 44.362202 PHE_277 68.062485 ASP_278 94.902039 ARG_279 113.549011 ASN_280 134.886017 ALA_281 72.340973 LEU_282 26.692348 THR_283 27.696728 ASP_284 72.214157 CYS_285 0.000000 SER_286 28.209335 ASP_287 64.560753 VAL_288 7.040061 ILE_289 8.665112 PRO_290 48.682365 SER_291 86.141670 ALA_292 29.031240 VAL_293 84.432014 SER_294 85.944153 ASN_295 49.017288 ASN_296 133.459198 ALA_297 57.283794 ALA_298 65.233749 PRO_299 24.751518 VAL_300 45.409184 ILE_301 8.060802 PRO_302 14.742939 GLY_303 16.589832 GLY_304 34.238071 LEU_305 24.719791 THR_306 49.356300 VAL_307 71.491821 ASP_308 130.906174 ASP_309 31.733070 ILE_310 19.581894 GLU_311 81.414574 VAL_312 94.769890 SER_313 39.688896 CYS_314 9.998511 PRO_315 120.328018 SER_316 95.364319 GLU_317 65.560959 PRO_318 100.254364 PHE_319 46.284115 PRO_320 31.328060 GLU_321 177.602249 ILE_322 33.449741 ALA_323 46.892982 THR_324 79.976471 ALA_325 36.423820 SER_326 124.467422 GLY_327 28.219524 PRO_328 107.553696 LEU_329 86.789825 PRO_330 34.287163 SER_331 75.764053 LEU_332 32.840569 ALA_333 61.516434 PRO_334 82.389992 ALA_335 6.246871 PRO_336 56.750813 HEM_337 60.435017 CA_338 2.078997 CA_339 0.000000 NAG_340 141.534668 NAG_341 186.311371

Subset REST:

restmole.list

Subset REST:

ARP:9,69-70,125,127,133,299-301,334-336

restatom.list

Subset REST:

ARP:SER 9:N,CA,C,O,CB,OG

ARP:GLY 69:N,CA,C,O

ARP:GLN 70:N,CA,C,O,CB,CG,CD,OE1,NE2

ARP:GLY 125:N,CA,C,O

ARP:SER 127:N,CA,C,O,CB,OG

ARP:PRO 133:N,CA,CD,C,O,CB,CG

ARP:SER 299:N,CA,C,O,CB,OG

ARP:ALA 300:N,CA,C,O,CB

ARP:VAL 301:N,CA,C,O,CB,CG1,CG2

ARP:SER 334:N,CA,C,O,CB,OG

ARP:GLY 335:N,CA,C,O

ARP:PRO 336:N,CA,CD,C,O,CB,CG

Subset SUB5B:

sub5bmole.list

Subset SUB5B:

ARP:10-11,34,38,65-68,71-72,120-121,123-124,128-132,134,270,274,

ARP:297-298,302-303,311-312,332-333,337-338

sub5batom.list

Subset SUB5B:

ARP:VAL 10:N,CA,C,O,CB,CG1,CG2

ARP:THR 11:N,CA,C,O,CB,OG1,CG2

ARP:GLN 34:N,CA,C,O,CB,CG,CD,OE1,NE2

ARP:TYR 38:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

ARP:LEU 65:N,CA,C,O,CB,CG,CD1,CD2

ARP:THR 66:N,CA,C,O,CB,OG1,CG2

ARP:ALA 67:N,CA,C,O,CB

ARP:ALA 68:N,CA,C,O,CB

ARP:PHE 71:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:GLY 72:N,CA,C,O

ARP:PHE 120:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:ALA 121:N,CA,C,O,CB

ARP:ALA 123:N,CA,C,O,CB

ARP:VAL 124:N,CA,C,O,CB,CG1,CG2

ARP:ASN 128:N,CA,C,O,CB,CG,OD1,ND2

ARP:CYS 129:N,CA,C,O,CB,SG

ARP:PRO 130:N,CA,CD,C,O,CB,CG

ARP:GLY 131:N,CA,C,O

ARP:SER 132:N,CA,C,O,CB,OG

ARP:ARG 134:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

ARP:GLY 270:N,CA,C,O

ARP:ARG 274:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

ARP:ILE 297:N,CA,C,O,CB,CG1,CG2,CD1

ARP:PRO 298:N,CA,CD,C,O,CB,CG

ARP:SER 302:N,CA,C,O,CB,OG

ARP:ASN 303:N,CA,C,O,CB,CG,OD1,ND2

ARP:GLY 311:N,CA,C,O

ARP:GLY 312:N,CA,C,O

ARP:THR 332:N,CA,C,O,CB,OG1,CG2

ARP:ALA 333:N,CA,C,O,CB

ARP:LEU 337:N,CA,C,O,CB,CG,CD1,CD2

ARP:PRO 338:N,CA,CD,C,O,CB,CG

Subset ACTSITE:

actsitemole.list

Subset ACTSITE:

ARP:44-61,75-77,79-80,87-88,90-96,99,118,122,126,135,148-149,152-158,

ARP:163-164,167,176-194,197-205,207-209,211-213,216,230-231,241,

ARP:243-246,249,259,273,277,280,343-347H

actsiteatom.list

Subset ACTSITE:

ARP:GLU 44:N,CA,C,O,CB,CG,CD,OE1,OE2

ARP:SER 45:N,CA,C,O,CB,OG

ARP:PRO 46:N,CA,CD,C,O,CB,CG

ARP:VAL 47:N,CA,C,O,CB,CG1,CG2

ARP:ARG 48:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

ARP:LYS 49:N,CA,C,O,CB,CG,CD,CE,NZ

ARP:ILE 50:N,CA,C,O,CB,CG1,CG2,CD1

ARP:LEU 51:N,CA,C,O,CB,CG,CD1,CD2

ARP:ARG 52:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

ARP:ILE 53:N,CA,C,O,CB,CG1,CG2,CD1

ARP:VAL 54:N,CA,C,O,CB,CG1,CG2

ARP:PHE 55:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:HIS 56:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

ARP:ASP 57:N,CA,C,O,CB,CG,OD1,OD2

ARP:ALA 58:N,CA,C,O,CB

ARP:ILE 59:N,CA,C,O,CB,CG1,CG2,CD1

ARP:GLY 60:N,CA,C,O

ARP:PHE 61:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:GLY 15:N,CA,C,O

ARP:ALA 76:N,CA,C,O,CB

ARP:ASP 77:N,CA,C,O,CB,CG,OD1,OD2

ARP:SER 79:N,CA,C,O,CB,OG

ARP:ILE 80:N,CA,C,O,CB,CG1,CG2,CD1

ARP:GLU 87:N,CA,C,O,CB,CG,CD,OE1,OE2

ARP:LEU 88:N,CA,C,O,CB,CG,CD1,CD2

ARP:PHE 90:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:PRO 91:N,CA,CD,C,O,CB,CG

ARP:ALA 92:N,CA,C,O,CB

ARP:ASN 93:N,CA,C,O,CB,CG,OD1,ND2

ARP:GLY 94:N,CA,C,O

ARP:GLY 95:N,CA,C,O

ARP:LEU 96:N,CA,C,O,CB,CG,CD1,CD2

ARP:THR 99:N,CA,C,O,CB,OG1,CG2

ARP:ILE 118:N,CA,C,O,CB,CG1,CG2,CD1

ARP:THR 122:N,CA,C,O,CB,OG1,CG2

ARP:MET 126:N,CA,C,O,CB,CG,SD,CE

ARP:LEU 135:N,CA,C,O,CB,CG,CD1,CD2

ARP:SER 148:N,CA,C,O,CB,OG

ARP:PRO 149:N,CA,CD,C,O,CB,CG

ARP:LEU 152:N,CA,C,O,CB,CG,CD1,CD2

ARP:ILE 153:N,CA,C,O,CB,CG1,CG2,CD1

ARP:PRO 154:N,CA,CD,C,O,CB,CG

ARP:GLY 155:N,CA,C,O

ARP:PRO 156:N,CA,CD,C,O,CB,CG

ARP:GLY 157:N,CA,C,O

ARP:ASN 158:N,CA,C,O,CB,CG,OD1,ND2

ARP:ILE 163:N,CA,C,O,CB,CG1,CG2,CD1

ARP:LEU 164:N,CA,C,O,CB,CG,CD1,CD2

ARP:MET 167:N,CA,C,O,CB,CG,SD,CE

ARP:GLU 176:N,CA,C,O,CB,CG,CD,OE1,OE2

ARP:VAL 177:N,CA,C,O,CB,CG1,CG2

ARP:VAL 178:N,CA,C,O,CB,CG1,CG2

ARP:ASP 179:N,CA,C,O,CB,CG,OD1,OD2

ARP:LEU 180:N,CA,C,O,CB,CG,CD1,CD2

ARP:LEU 181:N,CA,C,O,CB,CG,CD1,CD2

ARP:ALA 182:N,CA,C,O,CB

ARP:ALA 183:N,CA,C,O,CB

ARP:HIS 184:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

ARP:SER 185:N,CA,C,O,CB,OG

ARP:LEU 186:N,CA,C,O,CB,CG,CD1,CD2

ARP:ALA 187:N,CA,C,O,CB

ARP:SER 188:N,CA,C,O,CB,OG

ARP:GLN 189:N,CA,C,O,CB,CG,CD,OE1,NE2

ARP:GLU 190:N,CA,C,O,CB,CG,CD,OE1,OE2

ARP:GLY 191:N,CA,C,O

ARP:LEU 192:N,CA,C,O,CB,CG,CD1, CD2

ARP:ASN 193:N,CA,C,O,CB,CG,OD1,ND2

ARP:SER 194:N,CA,C,O,CB,OG

ARP:PHE 197:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:ARG 198:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

ARP:SER 199:N,CA,C,O,CB,OG

ARP:PRO 200:N,CA,CD,C,O,CB,CG

ARP:LEU 201:N,CA,C,O,CB,CG,CD1,CD2

ARP:ASP 202:N,CA,C,O,CB,CG,OD1,OD2

ARP:SER 203:N,CA,C,O,CB,OG

ARP:THR 204:N,CA,C,O,CB,OG1,CG2

ARP:PRO 205:N,CA,CD,C,O,CB,CG

ARP:VAL 207:N,CA,C,O,CB,CG1,CG2

ARP:PHE 208:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:ASP 209:N,CA,C,O,CB,CG,OD1,OD2

ARP:GLN 211:N,CA,C,O,CB,CG,CD,OE1,NE2

ARP:PHE 212:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:TYR 213:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

ARP:THR 216:N,CA,C,O,CB,OG1,CG2

ARP:PHE 230:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:ALA 231:N,CA,C,O,CB

ARP:PHE241:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

ARP:MET 243:N,CA,C,O,CB,CG,SD,CE

ARP:ARG 244:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

ARP:SER 245:N,CA,C,O,CB,OG

ARP:ASP 246:N,CA,C,O,CB,CG,OD1,OD2

ARP:LEU 249:N,CA,C,O,CB,CG,CD1,CD2

ARP:TRP 259:N,CA,C,O,CB,CG,CD1,

CD2,NE1,CE2,CE3,CZ2,CZ3,CH2

ARP:TYR 273:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

ARP:MET 277:N,CA,C,O,CB,CG,SD,CE

ARP:MET 280:N,CA,C,O,CB,CG,SD,CE

ARP:ALA 343:N,CA,C,O,CB

ARP:PRO 344:N,CA,CD,C,O,OXT,CB,CG

ARP:HEM 345H:FE,NA,NB,NC,ND,CHA,CHB, CHC,CHD,C1A,C2A,C3A,C4A,CMA,CAA,CBA,CGA

ARP:HEM 345H:O1A,O2A,C1B,C2B,C3B,C4B,CMB, CAB,CBB,C1C,C2C,C3C,C4C,CMC,CAC,CBC

ARP:HEM 345H:C1D,C2D,C3D,C4D,CMD,CAD,CBD,CGD,O1D,O2D

ARP:CA 346H:CA

ARP:CA 347H:CA

Subset RESTx:

restxmole.list

Subset RESTX

NEWMODEL:9,334-336

restxatom.list

Subset RESTX:

NEWMODEL:SER 9:N,CA,C,O,CB,OG

NEWMODEL:SER 334:N,CA,C,O,CB,OG

NEWMODEL:GLY 335:N,CA,C,O

NEWMODEL:PRO 336:N,CA,CD,C,O,CB,CG

Example 5

Activation of mPEG 15,000 With N-succinimidyl Carbonate

mPEG 15,000 was suspended in toluene (4 ml/g of mPEG) 20% was distilled off at normal pressure to dry the reactants azeotropically. Dichloromethane (dry 1 ml/g mPEG) was added when the solution was cooled to 30° C. and phosgene in toluene (1.93 M 5 mole/mole mPEG) was added and mixture stirred at room temperature overnight. The mixture was evaporated to dryness and the desired product was obtained as waxy lumps.

After evaporation dichloromethane and toluene (1:2, dry 3 ml/g mPEG) was added to re-dissolve the white solid. N-Hydroxy succinimide (2 mole/mole mPEG.) was added as a solid and then triethylamine (1.1 mole/mole mPEG). The mixture was stirred for 3 hours. initially unclear, then clear and ending with a small precipitate. The mixture was evaporated to dryness and recrystallized from ethyl acetate (10ml) with warm filtration to remove salts and insoluble traces. The blank liquid was left for slow cooling at ambient temperature for 16 hours and then in the refrigerator, overnight. The white precipitate was filtered and washed with a little cold ethyl acetate and dried to yield 98% (w/w). NMR Indicating 80-90% activation and 5 o/oo (w/w) HNEt₃Cl. ¹H-NMR for mPEG 15,000 (CDCl₃) d 1.42 t (I=4.8 CH₃ i HNEt₃Cl), 2.84 s (I=3.7 succinimide), 3.10 dq (I=3.4 CH₂ i HNEt₃Cl), 3.38 s (I=2.7 CH₃ i OMe), 3.40* dd (I=4.5 o/oo, ¹³C satellite), 3.64 bs (I=1364 main peak), 3.89* dd (I=4.8 o/oo, ¹³C satellite), 4.47 dd (I=1.8, CH2 in PEG). No change was seen after storage in a desiccator at 22° C. for 4 months.

Example 6

Activation of mPEG 5,000 With N-succinimidyl Carbonate

Activation of mPEG 5,000 with N-succinimidyl carbonate was performed as described in Example 5.

Example 7

Construction and Expression of PD498 Variants:

PD498 site-directed variants were constructed using the “maxioligonucleotide-PCR” method described by Sarkar et al., (1990): BioTechniques 8: 404-407.

The template plasmid was shuttle vector pPD498 or an analogue of this containing a variant of the PD498 protease gene.

The following PD498 variants were constructed, expressed and purified.

A: R28K

B: R62K

C: R169K

D: R28K+R62K

E: R28K+R169K

F: R62K+R169K

G: R28K+R69K+R169K

Construction of Variants

For introduction of the R28K substitution a synthetic oligonucleotide having the sequence: GGG ATG TAA CCA AGG GAA GCA GCA CTC AAA CG (SEQ ID NO. 7) was used.

A PCR fragment of 769 bp was ligated into the pPD498 plasmid prepared by Bst E II and Bgl II digestion. Positive variants were recognized by StyI digestion and verified by DNA sequencing of the total 769 bp insert.

For introduction of the R62K substitution a synthetic oligonucleotide having the sequence: CGA CTT TAT CGA TAA GGA CAA TAA CCC (SEQ ID NO. 8) was used.

A PCR fragment of 769 bp was ligated into the pPD498 plasmid prepared by Bst E II and Bgl II digestion. Positive variants were recognized by ClaI digestion and verified by DNA sequencing of the total 769 bp insert.

For introduction of the R169K substitution a synthetic oligonucleotide having the sequence: CAA TGT ATC CAA AAC GTT CCA ACC AGC (SEQ ID NO. 9) was used.

A PCR fragment of 769 bp was ligated into the pPD498 plasmid prepared by.Bst E II and Bgl II digestion. Positive variants were recognized by the absence of a Rsa I restriction site and verified by DNA sequencing of the total 769 bp insert.

For simultaneous introduction of the R28K and the R62K substitutions, synthetic oligonucleotides having the sequence: GGG ATG TAA CCA AGG GAA GCA GCA CTC AAA CG (SEQ ID NO. 7) and the sequence: CGA CTT TAT CGA TAA GGA CAA TAA CCC (SEQ ID No. 8) were used simultaneous. A PCR fragment of 769 bp was ligated into the pPD498 plasmid prepared by Bst E II and Bgl II digestion. Positive variants were recognized by StyI and ClaI digestion and verified by DNA sequencing of the total 769 bp insert.

For simultaneous introduction of the R28K and the R169K substitutions, synthetic oligonucleotides having the sequence: GGG ATG TAA CCA AGG GAA GCA GCA CTC AAA CG (SEQ ID NO. 7) and the sequence: CAA TGT ATC CAA AAC GTT CCA ACC AGC (SEQ ID NO. 9) were used simultaneously. A PCR fragment of 769 bp was ligated into the pPD498 plasmid prepared by Bst E II and Bgl II digestion. Positive variants were recognized by StyI digestion and absence of a Rsa I site. The variant was verified by DNA sequencing of the total 769 bp insert.

For simultaneous introduction of the R62K and the R169K substitutions, synthetic oligonucleotides having the sequence: CGA CTT TAT CGA TAA GGA CAA TAA CCC (SEQ ID NO. 8) and the sequence: CAA TGT ATC CAA AAC GTT CCA ACC AGC (SEQ ID NO. 9) were used simultaneously. A PCR fragment of 769 bp was ligated into the pPD498 plasmid prepared by Bst E II and Bgl II digestion. Positive variants were recognized by ClaI digestion and absence of a Rsa I site. The variant was verified by DNA sequencing of the total 769 bp insert.

For simultaneous introduction of the R28K, the R62K and the 169K substitutions, synthetic oligonucleotides having the sequence: GGG ATG TAA CCA AGG GAA GCA GCA CTC AAA CG (SEQ ID No. 7) the sequence: CGA CTT TAT CGA TAA GGA CAA TAA CCC (SEQ ID NO. 8) and the sequence: CAA TGT ATC CAA AAC GTT CCA ACC AGC (SEQ ID NO. 9) were used simultaneously. A PCR fragment of 769 bp was ligated into the pPD498 plasmid prepared by Bst E II and Bgl II digestion. Positive variants were recognized by StyI and ClaI digestion and absence of a Rsa I site. The variant was verified by DNA sequencing of the total 769 bp insert.

Fermentation, Expression and Purification of PD498 Variants

Vectors hosting the above mentioned PD498 variants were purified from E. coli cultures and transformed into B. subtilis in which organism the variants were fermented, expressed and purified as described in the “Materials and Methods” section above.

Example 7

Conjugation of Triple Substituted PD498 Variant With Activated mPEG 5,000

200 mg of triple substituted PD498 variant (i.e. the R28K+R62K+R169K substituted variant) was incubated in 50 mm NaBorate, pH 10, with 1.8 g of activated mPEG 5,000 with N-succinimidyl carbonate (prepared according to Example 2), in a final volume of 20 ml. The reaction was carried out at ambient temperature using magnetic stirring. Reaction time was 1 hour. The reaction was stopped by adding DMG buffer to a final concentration of 5 mM dimethyl glutarate, 1 mM CaCl₂ and 50 mM borate, pH 5.0.

The molecule weight of the obtained derivative was approximately 120 kDa, corresponding to about 16 moles of mPEG attached per mole enzyme.

Compared to the parent enzyme, residual activity was close to 100% towards peptide substrate (succinyl-Ala-Ala-Pro-Phe-p-Nitroanilide).

Example 8

Allergenicity Trails of PD498 Variant-SPEG5.000 in Guinea Pigs

Dunkin Hartley guinea pigs are stimulated with 1.0 μg PD498-SPEG 5,000 and 1.0 μg modified variant PD498-SPEG 5,000 by intratracheal installation.

Sera from immunized Dunkin Hartley guinea pigs are tested during the trial period in a specific IgG, ELISA (described above) to elucidate whether the molecules could activate the immune response system giving rise to a specific IgG₁ response indicating an allergenic response.

The IgG₁ levels of Dunkin Hartley guinea pigs during the trail period of 10 weeks are observed.

Example 9

Suitable Substitutions in Humicola lanuginosa Lipase for Addition of Amino Attachment Groups (—NH₂)

The 3D structure of Humicola lanuginosa lipase (SEQ ID NO 6) is available in Brookhaven Databank as 1tib.pdb. The lipase consists of 269 amino acids.

The procedure described in Example 1 was followed. The sequence of H. lanuginosa lipase is shown below in the table listing solvent accessibility data for H. lanuginosa lipase. H. lanuginosa residue numbering is used (1-269), and the active site residues (functional site) are S146, S201 and H258. The synonym TIB is used for H. lanuginosa lipase.

The commands performed in Insight (BIOSYM) are shown in the command files makeKzone.bcl and makeKzone2.bcl below:

Conservative Substitutions:

makeKzone.bcl

1 Delete Subset *

2 Color Molecule Atoms * Specified Specification 255,0,255

3 Zone Subset LYS :lys:NZ Static monomer/residue 10 Color_Subset 255,255,0

4 Zone Subset NTERM :1:N Static monomer/residue 10 Color_Subset 255,255,0

5 #NOTE: editnextline ACTSITE residues according to the protein

6 Zone Subset ACTSITE :146,201,258 Static monomer/residue 8 Color_Subset 255,255,0

7 Combine Subset ALLZONE Union LYS NTERM

8 Combine Subset ALLZONE Union ALLZONE ACTSITE

9 #NOTE: editnextline object name according to the protein

10 Combine Subset REST Difference TIB ALLZONE

11 List Subset REST Atom Output_File restatom.list

12 List Subset REST monomer/residue Output_File restmole.list

13 Color Molecule Atoms ACTSITE Specified Specification 255,0,0

14 List Subset ACTSITE Atom Output_File actsiteatom.list

15 List Subset ACTSITE monomer/residue.Output_File actsitemole.list

16 #

17 Zone Subset REST5A REST Static Monomer/Residue 5—Color_Subset

18 Combine Subset SUB5A Difference REST5A ACTSITE

19 Combine Subset SUB5B Difference SUB5A REST

20 Color Molecule Atoms SUB5B Specified Specification 255,255,255

21 List Subset SUB5B Atom Output_File sub5batom.list

22 List Subset SUB5B monomer/residue Output_File sub5bmole.list

23 #Now identify sites for lys→arg substitutions and continue with makezone2.bcl

24 #Use grep command to identify ARG in restatom.list, sub5batom.list & accsiteatom.list

Comments:

In this case of H. lanuginosa (=TIB), REST contains the Arginines Arg133, Arg139, Arg160, Arg179 and Arg 209, and SUB5B contains Arg118 and R125.

These residues are all solvent exposed. The substitutions R133K, R139K, R160K, R179K, R209K, R118K and R125K are identified in TIB as sites for mutagenesis within the scope of this invention. The residues are substituted below in section 2, and further analysis done. The subset ACTSITE contains no lysines.

Non-conservative Substitutions:

makeKzone2.bcl

1 #sourcefile makezone2.bcl Claus-von der Osten 961128

2 #

3 #having scanned lists (grep arg command) and identified sites for lys→arg substitutions

4 #NOTE: editnextline object name according to protein

5 Copy Object -To_Clipboard -Displace TIB newmodel

6 Biopolymer

7 #NOTE: editnextline object name according to protein

8 Blank Object On TIB

9 #NOTE: editnextlines with lys→arg positions

10 Replace Residue newmodel:118 lys L

11 Replace Residue newmodel:125 lys L

12 Replace Residue newmodel:133 lys L

13 Replace Residue newmodel:139 lys L

14 Replace Residue newmodel:160 lys L

15 Replace Residue newmodel:179 lys L

16 Replace Residue newmodel:209 lys L

17 #

18 #Now repeat analysis done prior to arg→lys, now including introduced lysines

19 Color Molecule Atoms newmodel Specified Specification 255,0,255

20 Zone Subset LYSx newmodel:lys:NZ Static monomer/residue 10 Color_Subset 255,255,0

21 Zone Subset NTERMx newmodel:1:N Static monomer/residue 10 Color_Subset 255,255,0

22 #NOTE: editnextline ACTSITEx residues according to the protein

23 Zone Subset ACTSITEx newmodel:146,201,258 Static monomer/residue 8 Color_Subset 255,255,0

24 Combine Subset ALLZONEx Union LYSx NTERMx

25 Combine Subset ALLZONEx Union ALLZONEx ACTSITEx

26 Combine Subset RESTX Difference newmodel ALLZONEx

27 List Subset RESTX Atom Output_File restxatom.list

28 List Subset RESTX monomer/residue Output_File restxmole.list

29 #

30 Color Molecule Atoms ACTSITEx Specified Specification 255,0,0

31 List Subset ACTSITEx Atom Output_File actsitexatom.list

32 List Subset ACTSITEx monomer/residue Output_File actsitexmole.list

33 #

34 #read restxatom.list or restxmole.list to identify sites for (not_arg)→lys subst. if needed

Comments:

Of the residues in RESTX, the following are >5% exposed (see lists below): 18,31-33,36,38,40,48,50,56-62,64,78,88,91-93,104-106,120,136,225,227-229,250,262,268. Of these three are Cysteines involved in disulfide bridge formation, and consequently for structural reasons excluded from the residues to be mutated. The following mutations are proposed in H. lanuginosa lipase (TIB): A18K,G31K,T32K,N33K,G38K,A40K,D48K,T50K,E56K,D57K,S58K,G59K, V60K,G61K,D62K,T64K,L78K,N88K,G91K,N92K,L93K,S105K,G106K, V120K,P136K,G225K,L227K,V228K,P229K,P250K,F262K. Relevant data for Example 2:

# TIBNOH2O # residue area GLU_1 110.792610 VAL_2 18.002457 SER_3 53.019516 GLN_4 85.770164 ASP_5 107.565826 LEU_6 33.022659 PHE_7 34.392754 ASN_8 84.855331 GLN_9 39.175591 PHE_10 2.149547 ASN_11 40.544380 LEU_12 27.648788 PHE_13 2.418241 ALA_14 4.625293 GLN_15 28.202387 TYR_16 0.969180 SER_17 0.000000 ALA_18 7.008336 ALA_19 0.000000 ALA_20 0.000000 TYR_21 6.947358 CYS_22 8.060802 GLY_23 32.147034 LYS_24 168.890747 ASN_25 8.014721 ASN_26 11.815564 ASP_27 92.263428 ALA_28 18.206699 PRO_29 83.188431 ALA_30 69.428421 GLY_31 50.693439 THR_32 52.171135 ASN_33 111.230743 ILE_34 2.801945 THR_35 82.130569 CYS_36 17.269245 THR_37 96.731941 GLY_38 77.870995 ASN_39 123.051003 ALA_40 27.985256 CYS_41 0.752820 PRO_42 46.258949 GLU_43 69.773987 VAL_44 0.735684 GLU_45 77.169510 LYS_46 141.213562 ALA_47 10.249716 ASP_48 109.913902 ALA_49 2.602721 THR_50 32.012184 PHE_51 8.255627 LEU_52 60.093613 TYR_53 77.877937 SER_54 26.980494 PHE_55 10.747735 GLU_56 112.689758 ASP_57 92.064278 SER_58 32.990780 GLY_59 53.371807 VAL_60 83.563644 GLY_61 69.625633 ASP_62 75.520988 VAL_63 4.030401 THR_64 8.652839 GLY_65 0.000000 PHE_66 0.268693 LEU_67 11.822510 ALA_68 0.537387 LEU_69 30.243870 ASP_70 0.000000 ASN_71 84.101044 THR_72 89.271126 ASN_73 70.742401 LYS_74 98.319168 LEU_75 8.329495 ILE_76 5.197878 VAL_77 0.806080 LEU_78 5.293978 SER_79 0.000000 PHE_80 2.079151 ARG_81 41.085312 GLY_82 1.471369 SER_83 43.794014 ARG_84 100.26127 SER_85 70.607552 ILE_86 59.696865 GLU_87 136.510773 ASN_88 119.376373 TRP_89 102.851227 ILE_90 78.068588 GLY_91 60.783607 ASN_92 45.769428 LEU_93 134.228363 ASN_94 101.810959 PHE_95 41.212212 ASP_96 79.645950 LEU_97 25.281572 LYS_98 88.840263 GLU_99 132.377090 ILE_100 9.135575 ASN_101 63.444527 ASP_102 88.652847 ILE_103 33.470661 CYS_104 11.553816 SER_105 99.461174 GLY_106 40.325161 CYS_107 4.433561 ARG_108 97.450104 GLY_109 1.343467 HIS_110 4.652464 ASP_111 37.023655 GLY_112 29.930408 PHE_113 14.976435 THR_114 10.430954 SER_115 40.606895 SER_116 13.462922 TRP_117 10.747735 ARG_118 114.364281 SER_119 46.880249 VAL_120 13.434669 ALA_121 18.258261 ASP_122 110.753098 THR_123 69.641922 LEU_124 17.090784 ARG_125 73.929977 GLN_126 101.320190 LYS_127 84.450241 VAL_128 6.448641 GLU_129 47.700993 ASP_130 75.529091 ALA_131 11.340775 VAL_132 27.896025 ARG_133 153.136490 GLU_134 132.140594 HIS_135 54.553406 PRO_136 97.386963 ASP_137 22.653191 TYR_138 35.392658 ARG_139 74.321243 VAL_140 10.173222 VAL_141 0.233495 PHE_142 3.224321 THR_143 0.000000 GLY_144 0.000000 HIS_145 4.514527 SER_146 15.749787 LEU_147 40.709171 GLY_148 0.000000 GLY_149 0.000000 ALA_150 0.537387 LEU_151 22.838938 ALA_152 0.268693 THR_153 18.078798 VAL_154 7.254722 ALA_155 0.000000 GLY_156 0.000000 ALA_157 15.140230 ASP_158 41.645477 LEU_159 6.144750 ARG_160 41.939716 GLY_161 68.978180 ASN_162 68.243805 GLY_163 79.181274 TYR_164 36.190247 ASP_165 103.068283 ILE_166 0.000000 ASP_167 24.326443 VAL_168 4.299094 PHE_169 0.466991 SER_170 3.339332 TYR_171 0.000000 GLY_172 0.000000 ALA_173 12.674671 PRO_174 13.117888 ARG_175 10.004488 VAL_176 21.422220 GLY_177 2.680759 ASN_178 21.018063 ARG_179 110.282166 ALA_180 33.210381 PHE_181 4.567788 ALA_182 3.897251 GLU_183 76.354004 PHE_184 71.225983 LEU_185 24.985012 THR_186 47.023815 VAL_187 98.244606 GLN_188 54.152954 THR_189 88.660645. GLY_190 24.792120 GLY_191 10.726818 THR_192 45.458744 LEU_193 16.633211 TYR_194 34.829491 ARG_195 29.030851 ILE_196 1.973557 THR_197 3.493014 HIS_198 1.532270 THR_199 34.785877 ASN_200 39.789238 ASP_201 0.000000 ILE_202 31.168434 VAL_203 29.521076 PRO_204 3.515322 ARG_205 44.882454 LEU_206 51.051746 PRO_207 12.575329 PRO_208 43.259636 ARG_209 113.700233 GLU_210 154.628540 PHE_211 112.505188 GLY_212 30.084938 TYR_213 3.268936 SER_214 12.471436 HIS_215 23.354481 SER_216 16.406200 SER_217 14.665598 PRO_218 17.240993 GLU_219 13.145291 TYR_220 18.718306 TRP_221 39.229233 ILE_222 5.105175 LYS_223 120.739983 SER_224 15.407301 GLY_225 29.306646 THR_226 66.806862 LEU_227 122.682808 VAL_228 60.923004 PRO_229 104.620377 VAL_230 23.398251 THR_231 63.372971 ARG_232 80.357857 ASN_233 89.255066 ASP_234 43.011250 ILE_235 2.114349 VAL_236 45.140491 LYS_237 105.651306 ILE_238 24.671705 GLU_239 116.891907 GLY_240 31.965794 ILE_241 46.278099 ASP_242 28.963699 ALA_243 25.158146 THR_244 98.351440 GLY_245 43.842186 GLY_246 0.700486 ASN_247 3.926274 ASN_248 51.047890 GLN_249 66.699188 PRO_250 132.414047 ASN_251 70.213730 ILE_252 141.498062 PRO_253 59.089233 ASP_254 59.010895 ILE_255 63.298943 PRO_256 78.608688 ALA_257 0.806080 HIS_258 3.761708 LEU_259 50.747856 TRP_260 35.229710 TYR_261 5.440791 PHE_262 36.457939 GLY_263 22.071375 LEU_264 109.148178 ILE_265 2.418241 GLY_266 17.730062 THR_267 68.217873 CYS_268 15.418195 LEU_269 165.990997

Subset REST:

restmole.list

Subset REST:

TIB:5,8-9,13-14,16,18-20,31-34,36,38,40,48-80,56-66,68,76-79,88,91-93,

TIB:100-107,116-117,119-121,132-134,136,139-142,154-40 169,177-185,

TIB:187,189-191,207-212,214-216,225,227-229,241-244,250,262,268

restatom.list

Subset REST:

TIB:ASP 5:N,CA,C,O,CB,CG,OD1,OD2

TIB:ASN 8:N,CA,C,O,CB,CG,OD1,ND2

TIB:GLN 9:N,CA,C,O,CB,CG,CD,OE1,NE2

TIB:PHE 13:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:ALA 14:N,CA,C,0,CB

TIB:TYR 16:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:ALA 18:N,CA,C,0,CB

TIB:ALA 19:N,CA,C,O,CB

TIB:ALA 20:N,CA,C,O,CB

TIB:GLY 31:N,CA,C,O

TIB:THR 32:N,CA,C,O,CB,OG1,CG2

TIB:ASN 33:N,CA,C,O,CB,CG,OD1,ND2

TIB:ILE 34:N,CA,C,O,CB,CG1,CG2,CD1

TIB:CYS 36:N,CA,C,O,CB,SG

TIB:GLY 38:N,CA,C,O

TIB:ALA 40:N,CA,C,O,CB

TIB:ASP 48:N,CA,C,O,CB,CG,OD1,OD2

TIB:ALA 49:N,CA,C,O,CB

TIB:THR 50:N,CA,C,O,CB,OG1,CG2

TIB:GLU 56:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:ASP 57:N,CA,C,O,CB,CG,OD1,OD2

TIB:SER 58:N,CA,C,O,CB,OG

TIB:GLY 59:N,CA,C,O

TIB:VAL 60:N,CA,C,O,CB,CG1,CG2

TIB:GLY 61:N,CA,C,O

TIB:ASP 62:N,CA,C,O,CB,CG,OD1,OD2

TIB:VAL 63:N,CA,C,O,CB,CG1,CG2

TIB:THR 64:N,CA,C,O,CB,OG1,CG2

TIB:GLY 65:N,CA,C,O

TIB:PHE 66:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:ALA 68:N,CA,C,O,CB

TIB:ILE 76:N,CA,C,O,CB,CG1,CG2,CD1

TIB:VAL 77:N,CA,C,O,CB,CG1,CG2

TIB:LEU 78:N,CA,C,O,CB,CG,CD1,CD2

TIB:SER 79:N,CA,C,O,CB,OG

TIB:ASN 88:N,CA,C,O,CB,CG,OD1,ND2

TIB:GLY 91:N,CA,C,O

TIB:ASN 92:N,CA,C,O,CB,CG,OD1,ND2

TIB:LEU 93:N,CA,C,O,CB,CG,CD1,CD2

TIB:ILE 100:N,CA,C,O,CB,CG1,CG2,CD1

TIB:ASN 101:N,CA,C,O,CB,CG,OD1,ND2

TIB:ASP 102:N,CA,C,O,CB,CG,OD1,OD2

TIB:ILE 103:N,CA,C,O,CB,CG1,CG2,CD1

TIB:CYS 104:N,CA,C,O,CB,SG

TIB:SER 105:N,CA,C,O,CB,OG

TIB:GLY 106:N,CA,C,O

TIB:CYS 107:N,CA,C,O,CB,SG

TIB:SER 116:N,CA,C,O,CB,OG

TIB:TRP 117:N,CA,C,O,CB,CG,CD1,CD2,NE1,CE2, CE3,CZ2,CZ3,CH2

TIB:SER 119:N,CA,C,O,CB,OG

TIB:VAL 120:N,CA,C,O,CB,CG1,CG2

TIB:ALA 121:N,CA,C,O,CB

TIB:VAL 132:N,CA,C,O,CB,CG1,CG2

TIB:ARG 133:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:GLU 134:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:PRO 136:N,CA,CD,C,O,CB,CG

TIB:ARG 139:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:VAL 140:N,CA,C.,O,CB,CG1,CG2

TIB:VAL 141:N,CA,C,O,CB,CG1,CG2

TIB:PHE 142:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:VAL 154:N,CA,C,O,CB,CG1,CG2

TIB:ALA 155:N,CA,C,O,CB

TIB:GLY 156:N,CA,C,O

TIB:ALA 157:N,CA,C,O,CB

TIB:ASP 158:N,CA,C,O,CB,CG,OD1,OD2

TIB:LEU 159:N,CA,C,O,CB,CG,CD1,CD2

TIB:ARG 160:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:GLY 161:N,CA,C,O

TIB:ASN 162:N,CA,C,O,CB,CG,OD1,ND2

TIB:GLY 163:N,CA,C,O

TIB:TYR 164:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:ASP 165:N,CA,C,O,CB,CG,OD1,OD2

TIB:ILE 166:N,CA,C,O,CB,CG1,CG2,CD1

TIB:ASP 167:N,CA,C,O,CB,CG,OD1,OD2

TIB:VAL 168:N,CA,C,O,CB,CG1,CG2

TIB:PHE 169:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:GLY 177:N,CA,C,O

TIB:ASN 178:N,CA,C,O,CB,CG,OD1,ND2

TIB:ARG 179:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:ALA 180:N,CA,C,O,CB

TIB:PHE 181:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:ALA 182:N,CA,C,O,CB

TIB:GLU 183:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:PHE 184:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:LEU 185:N,CA,C,O,CB,CG,CD1,CD2

TIB:VAL 187:N,CA,C,O,CB,CG1,CG2

TIB:THR 189:N,CA,C,O,CB,OG1,CG2

TIB:GLY 190:N,CA,C,O

TIB:GLY 191:N,CA,C,O

TIB:PRO 207:N,CA,CD,C,O,CB,CG

TIB:PRO 208:N,CA,CD,C,O,CB,CG

TIB:ARG 209:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:GLU 210:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:PHE 211:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:GLY 212:N,CA,C,O

TIB:SER 214:N,CA,C,O,CB,OG

TIB:HIS 215:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

TIB:SER 216:N,CA,C,O,CB,OG

TIB:GLY 225:N,CA,C,O

TIB:LEU 227:N,CA,C,O,CB,CG,CD1,CD2

TIB:VAL 228:N,CA,C,O,CB,CG1,CG2

TIB:PRO 229:N,CA,CD,C,O,CB,CG

TIB:ILE 241:N,CA,C,O,CB,CG1,CG2,CD1

TIB:ASP 242:N,CA,C,O,CB,CG,OD1,OD2

TIB:ALA 243:N,CA,C,O,CB

TIB:THR 244:N,CA,C,O,CB,OG1,CG2

TIB:PRO 250:N,CA,CD,C,O,CB,CG

TIB:PHE 262:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:CYS 268:N,CA,C,O,CB,SG

Subset SUB5B:

sub5mole.list

Subset SUB5B:

TIB:3-4,6-7,10-12,15,22-23,25-30,35,37,39,41-42,44-47,51-55,67,69-70,

TIB:72,74-75,94-99,108-112,114-115,118,122-126,128-131,135,137-138,

TIB:186,188,192-195,213,217-219,223-224,230-231,234-235,238-240,

TIB:245,269

sub5batom.list

Subset SUB5B:

TIB:SER 3:N,CA,C,O,CB,OG

TIB:GLN 4:N,CA,C,O,CB,CG,CD,OE1,NE2

TIB:LEU 6:N,CA,C,O,CB,CG,CD1,CD2

TIB:PHE 7:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:PHE 10:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:ASN 11:N,CA,C,O,CB,CG,OD1,ND2

TIB.:LEU 12:N,CA,C,O,CB,CG,CD1,CD2

TIB:GLN 15:N,CA,C,O,CB,CG,CD,OE1,NE2

TIB:CYS 22:N,CA,C,O,CB,SG

TIB:GLY 23:N,CA,C,O

TIB:ASN 25:N,CA,C,O,CB,CG,OD1,ND2

TIB:ASN 26:N,CA,C,O,CB,CG,OD1,ND2

TIB:ASP 27:N,CA,C,0,CB,CG,OD1,OD2

TIB:ALA 28:N,CA,C,O,CB

TIB:PRO 29:N,CA,CD,C,O,CB,CG

TIB:ALA 30:N,CA,C,O,CB

TIB:THR 35:N,CA,C,O,CB,OG1,CG2

TIB:THR 37:N,CA,C,O,CB,OG1,CG2

TIB:ASN 39:N,CA,C,O,CB,CG,OD1,ND2

TIB:CYS 41:N,CA,C,O,CB,SG

TIB:PRO 42:N,CA,CD,C,O,CB,CG

TIB:VAL 44:N,CA,C,O,CB,CG1,CG2

TIB:GLU-45:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:LYS 46:N,CA,C,O,CB,CG,CD,CE,NZ

TIB:ALA 47:N,CA,C,O,CB

TIB:PHE 51:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:LEU 52:N,CA,C,O,CB,CG,CD1,CD2

TIB:TYR 53:N,CA,C,O;CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:SER 54:N,CA,C,O,CB,OG

TIB:PHE 55:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:LEU 67:N,CA,C,O,CB,CG,CD1,CD2

TIB:LEU 69:N,CA,C,O,CB,CG,CD1,CD2

TIB:ASP 70:N,CA,C,O,CB,CG,OD1,OD2

TIB:THR 72:N,CA,C,O,CB,OG1,CG2

TIB:LYS 74:N,CA,C,O,CB,CG,CD,CE,NZ

TIB:LEU 75:N,CA,C,O,CB,CG,CD1,CD2

TIB:ASN 94:N,CA,C,O,CB,CG,OD1,ND2

TIB:PHE 95:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:ASP 96:N,CA,C,O,CB,CG,OD1,OD2

TIB:LEU 97:N,CA,C,O,CB,CG,CD1,CD2

TIB:LYS 98:N,CA,C,O,CB,CG,CD,CE,NZ

TIB:GLU 99:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:ARG 108:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:GLY 109:N,CA,C,O

TIB:HIS 110:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

TIB:ASP 111:N,CA,C,O,CB,CG,OD1,OD2

TIB:GLY 112:N,CA,C,O

TIB:THR 114:N,CA,C,O,CB,OG1,CG2

TIB:SER 115:N,CA,C,O,CB,OG

TIB:ARG 118:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:ASP 122:N,CA,C,O,CB,CG,OD1,OD2

TIB:THR 123:N,CA,C,O,CB,OG1,CG2

TIB:LEU 124:N,CA,C,O,CB,CG,CD1,CD2

TIB:ARG 125:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:GLN 126:N,CA,C,O,CB,CG,CD,OE1,NE2

TIB:VAL 128:N,CA,C,O,CB,CG1,CG2

TIB:GLU 129:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:ASP 130:N,CA,C,O,CB,CG,OD1,OD2

TIB:ALA 131:N,CA,C,O,CB

TIB:HIS 135:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

TIB:ASP 137:N,CA,C,O,CB,CG,OD1,OD2

TIB:TYR 138:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:THR 186:N,CA,C,O,CB,OG1,CG2

TIB:GLN 188:N,CA,C,O,CB,CG,CD,OE1,NE2

TIB:THR 192:N,CA,C,O,CB,OG1,CG2

TIB:LEU 193:N,CA,C,O,CB,CG,CD1,CD2

TIB:TYR 194:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:ARG 195:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:TYR 213:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:SER 217:N,CA,C,O,CB,OG

TIB:PRO 218:N,CA,CD,C,O,CB,CG

TIB:GLU 219:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:LYS 223:N,CA,C,O,CB,CG,CD,CE,NZ

TIB:SER 224:N,CA,C,O,CB,OG

TIB:VAL 230:N,CA,C,O,CB,CG1,CG2

TIB:THR 231:N,CA,C,O,CB,OG1,CG2

TIB:ASP 234:N,CA,C,O,CB,CG,OD1,OD2

TIB:ILE 235:N,CA,C,O,CB,CG1,CG2,CD1

TIB:ILE 238:N,CA,C,O,CB,CG1,CG2,CD1

TIB:GLU 239:N,CA,C, 0,CB,CG,CD,OE1,OE2

TIB:GLY 240:N,CA,C,O

TIB:GLY 245:N,CA,C,O

TIB:LEU 269:N,CA,C,O,CB,OXT,CG,CD1,CD2

Subset ACTSITE:

actsitemole.list

Subset ACTSITE:

TIB:17,21,80-87,89-90,113,143-153,170-176,196-206,221-222,226,246-249,

TIB:251-261,263-267

actsiteatom.list

Subset ACTSITE:

TIB:SER 17:N,CA,C,0,CB,OG

TIB:TYR 21:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:PHE 80:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:ARG 81:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:GLY 82:N,CA,C,O

TIB:SER 83:N,CA,C,O,CB,OG

TIB:ARG 84:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:SER 85:N,CA,C,O,CB,OG

TIB:ILE 86:N,CA,C,O,CB,CG1,CG2,CD1

TIB:GLU 87:N,CA,C,O,CB,CG,CD,OE1,OE2

TIB:TRP 89:N,CA,C,O,CB,CG,CD1,CD2,NE1,CE2,CE3,CZ2,CZ3,CH2

TIB:ILE 90:N,CA,C,O,CB,CG1,CG2,CD1

TIB:PHE 113:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

TIB:THR 143:N,CA,C,O,CB,OG1,CG2

TIB:GLY 144:N,CA,C,O

TIB:HIS 145:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

TIB:SER 146:N,CA,C,O,CB,OG

TIB:LEU 147:N,CA,C,O,CB,CG,CD1,CD2

TIB:GLY 148:N,CA,C,O

TIB:GLY 149:N,CA,C,O

TIB:ALA 150:N,CA,C,O,CB

TIB:LEU 151:N,CA,C,O,CB,CG,CD1,CD2

TIB:ALA 152:N,CA,C,O,CB

TIB:THR 153:N,CA,C,O,CB,OG1,CG2

TIB:SER 170:N,CA,C,O,CB,OG

TIB:TYR 171:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:GLY 172:N,CA,C,O

TIB:ALA 173:N,CA,C,O,CB

TIB:PRO 174:N,CA,CD,C,O,CB,CG

TIB:ARG 175:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:VAL 176:N,CA,C,O,CB,CG1,CG2

TIB:ILE 196:N,CA,C,O,CB,CG1,CG2,CD1

TIB:THR 197:N,CA,C,O,CB,OG1,CG2

TIB:HIS 198:N,CA,C,00CB,CG,ND1,CD2,CE1,NE2

TIB:THR 199:N,CA,C,O,CB,OG1,CG2

TIB:ASN 200:N,CA,C,O,CB,CG,OD1,ND2

TIB:ASP 201:N,CA,C,O,CB,CG,OD1,OD2

TIB:ILE 202:N,CA,C,O,CB,CG1,CG2,CD1

TIB:VAL 203:N,CA,C,O,CB,CG1,CG2

TIB:PRO 204:N,CA,CD,C,O,CB,CG

TIB:ARG 205:N,CA,C,O,CB,CG,CD,NE,CZ,NH1,NH2

TIB:LEU 206:N,CA,C,O,CB,CG,CD1,CD2

TIB:TRP 221:N,CA,C,O,CB,CG,CD1,CD2,NE1,CE2,CE3,CZ2,CZ3,CH2

TIB:ILE 222:N,CA,C,O,CB,CG1,CG2,CD1

TIB:THR 226:N,CA,C,O,CB,OG1,CG2

TIB:GLY 246:N,CA,C,O

TIB:ASN 247:N,CA,C,O,CB,CG,OD1,ND2

TIB:ASN 248:N,CA,C,O,CB,CG,OD1,ND2

TIB:GLN 249:N,CA,C,O,CB,CG,CD,OE1,NE2

TIB:ASN 251:N,CA,C,O,CB,CG,OD1,ND2

TIB:ILE 252:N,CA,C,O,CB,CG1,CG2,CD1

TIB:PRO 253:N,CA,CD,C,O,CB,CG

TIB:ASP 254:N,CA,C,O,CB,CG,OD1,OD2

TIB:ILE 255:N,CA,C,O,CB,CG1,CG2,CD1

TIB:PRO 256:N,CA,CD,C,O,CB,CG

TIB:ALA 257:N,CA,C,O,CB

TIB:HIS 258:N,CA,C,O,CB,CG,ND1,CD2,CE1,NE2

TIB:LEU 259:N,CA,C,O,CB,CG,CD1,CD2

TIB:TRP 260:N,CA,C,O,CB,CG,CD1,CD2,NE1,CE2,CE3,CZ2,CZ3,CH2

TIB:TYR 261:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

TIB:GLY 263:N,CA,C,O

TIB:LEU 264:N,CA,C,O,CB,CG,CD1,CD2

TIB:ILE 265:N,CA,C,O,CB,CG1,CG2,CD1

TIB:GLY 266:N,CA,C,O

TIB:THR 267:N,CA,C,O,CB,OG1,CG2

Subset RESTX:

restxmole.list

Subset RESTX:

NEWMODEL:14,16,18-20,31-34,36,38,40,48-50,56-66,68,78-79,88,91-93,

NEWMODEL:104-106,120,136,225,227-229,250,262,268

restxatom.list

Subset RESTX:

NEWMODEL:ALA 14:N,CA,C,O,CB

NEWMODEL:TYR 16:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ,OH

NEWMODEL:ALA 18:N,CA,C,O,CB

NEWMODEL:ALA 19:N,CA,C,O,CB

NEWMODEL:ALA 20:N,CA,C,O,CB

NEWMODEL:GLY 31:N,CA,C,O

NEWMODEL:THR 32:N,CA,C,O,CB,OG1,CG2

NEWMODEL:ASN 33:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:ILE 34:N,CA,C,O,CB,CG1,CG2,CD1

NEWMODEL:CYS 36:N,CA,C,O,CB,SG

NEWMODEL:GLY 38:N,CA,C,O

NEWMODEL:ALA 40:N,CA,C,O,CB

NEWMODEL:ASP 48:N,CA,C,O,CB,CG,OD1,OD2

NEWMODEL:ALA 49:N,CA,C,O,CB

NEWMODEL:THR 50:N,CA,C,O,CB,OG1,CG2

NEWMODEL:GLU 56:N,CA,C,O,CB,CG,CD,OE1,OE2

NEWMODEL:ASP 57:N,CA,C,O,CB,CG,OD1,OD2

NEWMODEL:SER 58:N,CA,C,O,CB,OG

NEWMODEL:GLY 59:N,CA,C,O

NEWMODEL:VAL 60:N,CA,C,O,CB,CG1,CG2

NEWMODEL:GLY 61:N,CA,C,O

NEWMODEL:ASP 62:N,CA,C,O,CB,CG,OD1,OD2

NEWMODEL:VAL 63:N,CA,C,O,CB,CG1,CG2

NEWMODEL:THR 64:N,CA,C,O,CB,OG1,CG2

NEWMODEL:GLY 65:N,CA,C,O

NEWMODEL:PHE 66:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

NEWMODEL:ALA 68:N,CA,C,O,CB

NEWMODEL:LEU 78:N,CA,C,O,CB,CG,CD1,CD2

NEWMODEL:SER 79:N,CA,C,O,CB,OG

NEWMODEL:ASN 88:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:GLY 91:N,CA,C,O

NEWMODEL:ASN 92:N,CA,C,O,CB,CG,OD1,ND2

NEWMODEL:LEU 93:N,CA,C,O,CB,CG,CD1,CD2

NEWMODEL:CYS 104:N,CA,C,O,CB,SG

NEWMODEL:SER 105:N,CA,C,O,CB,OG

NEWMODEL:GLY 106:N,CA,C,O

NEWMODEL:VAL 120:N,CA,C,O,CB,CG1,CG2

NEWMODEL:PRO 136:N,CA,CD,C,O,CB,CG

NEWMODEL:GLY 225:N,CA,C,O

NEWMODEL:LEU 227:N,CA,C,O,CB,CG,CD1,CD2

NEWMODEL:VAL 228:N,CA,C,O,CB,CG1,CG2

NEWMODEL:PRO 229:N,CA,CD,C,O,CB,CG

NEWMODEL:PRO 250:N,CA,CD,C,O,CB,CG

NEWMODEL:PHE 262:N,CA,C,O,CB,CG,CD1,CD2,CE1,CE2,CZ

NEWMODEL:CYS 268:N,CA,C,O,CB,SG

Example 10

Providing a Lipase Variant E87K+D254K

The Humicola lanuginosa lipase variant E87K+D254K was constructed, expressed and purified as described in WO 92/05249.

Example 11

Lipase-S-PEG 15,000 Conjugate

The lipase variant E87K+D254K-SPEG conjugate was prepared as described in Example 7, except that the enzyme is the Humicola lanuginosa lipase variant (E87K+D254K) described in Example 10 and the polymer is mPEG15,000.

Example 12

Immunogenecity Assessed as IgG, of Lipase Variant (D87K+D254K) in Balb/C Mice

Balb/c mice were immunized by subcutanuous injection of:

i) 50 μl 0.9% (wt/vol) NaCl solution (control group, 8 mice) (control),

ii) 50 μl 0.9% (wt/vol) NaCl solution containing 25 μg of protein of a Humicola lanuginosa lipase variant (E87K+D254K) (group 1, 8 mice) (unmodified lipase variant),

iii) 50% 0.9% (wt/vol) NaCl solution containing a Humicola lanugoinosa lipase variant substituted in position D87K+D254K and coupled to a N-succinimidyl carbonate activated mPEG 15,000(group 2, 8 mice) (lipase-SPEG15,000).

The amount of protein for each batch was measured by optical density measurements. Blood samples (200 p1) were collected from the eyes one week after the immunization, but before the following immunization. Serum was obtained by blood clotting, and centrifugation.

The IgG₁ response was determined by use of the Balb/C mice IgG, ELISA method as described above.

Results:

Five weekly immunizations were required to elicit a detectable humoral response to the unmodified Humicola lanuginosa variant. The antibody titers elicited by the conjugate (i.e. lipase-SPEG15,000 ranged between 960 and 1920, and were only 2 to 4× lower than the antibody titer of 3840 that was elicited by unmodified HL82-Lipolase (figure to the left).

The Results of the Tests are Shown in FIG. 1

As will be apparent to those skilled in the art, in the light of the foregoing disclosure, many alterations and modifications are possible in the practice of this invention without departing from the spirit or scope thereof. Accordingly, the scope of the invention is to be construed in accordance with the substance defined by the following claims.

SEQUENCE LISTING <160> NUMBER OF SEQ ID NOS: 9 <210> SEQ ID NO 1 <211> LENGTH: 840 <212> TYPE: DNA <213> ORGANISM: bacillus sp. <220> FEATURE: <221> NAME/KEY: CDS <222> LOCATION: (1)...(840) <400> SEQUENCE: 1 tgg tca ccg aat gac cct tac tat tct gct tac cag tat gga cca caa 48 Trp Ser Pro Asn Asp Pro Tyr Tyr Ser Ala Tyr Gln Tyr Gly Pro Gln 1 5 10 15 aac acc tca acc cct gct gcc tgg gat gta acc cgt gga agc agc act 96 Asn Thr Ser Thr Pro Ala Ala Trp Asp Val Thr Arg Gly Ser Ser Thr 20 25 30 caa acg gtg gcg gtc ctt gat tcc gga gtg gat tat aac cac cct gat 144 Gln Thr Val Ala Val Leu Asp Ser Gly Val Asp Tyr Asn His Pro Asp 35 40 45 ctt gca aga aaa gta ata aaa ggg tac gac ttt atc gac agg gac aat 192 Leu Ala Arg Lys Val Ile Lys Gly Tyr Asp Phe Ile Asp Arg Asp Asn 50 55 60 aac cca atg gat ctt aac gga cat ggt acc cat gtt gcc ggt act gtt 240 Asn Pro Met Asp Leu Asn Gly His Gly Thr His Val Ala Gly Thr Val 65 70 75 80 gct gct gat acg aac aat gga att ggc gta gcc ggt atg gca cca gat 288 Ala Ala Asp Thr Asn Asn Gly Ile Gly Val Ala Gly Met Ala Pro Asp 85 90 95 acg aag atc ctt gcc gta cgg gtc ctt gat gcc aat gga agt ggc tca 336 Thr Lys Ile Leu Ala Val Arg Val Leu Asp Ala Asn Gly Ser Gly Ser 100 105 110 ctt gac agc att gcc tca ggt atc cgc tat gct gct gat caa ggg gca 384 Leu Asp Ser Ile Ala Ser Gly Ile Arg Tyr Ala Ala Asp Gln Gly Ala 115 120 125 aag gta ctc aac ctc tcc ctt ggt tgc gaa tgc aac tcc aca act ctt 432 Lys Val Leu Asn Leu Ser Leu Gly Cys Glu Cys Asn Ser Thr Thr Leu 130 135 140 aag agt gcc gtc gac tat gca tgg aac aaa gga gct gta gtc gtt gct 480 Lys Ser Ala Val Asp Tyr Ala Trp Asn Lys Gly Ala Val Val Val Ala 145 150 155 160 gct gca ggg aat gac aat gta tcc cgt aca ttc caa cca gct tct tac 528 Ala Ala Gly Asn Asp Asn Val Ser Arg Thr Phe Gln Pro Ala Ser Tyr 165 170 175 cct aat gcc att gca gta ggt gcc att gac tcc aat gat cga aaa gca 576 Pro Asn Ala Ile Ala Val Gly Ala Ile Asp Ser Asn Asp Arg Lys Ala 180 185 190 tca ttc tcc aat tac gga acg tgg gtg gat gtc act gct cca ggt gtg 624 Ser Phe Ser Asn Tyr Gly Thr Trp Val Asp Val Thr Ala Pro Gly Val 195 200 205 aac ata gca tca acc gtt ccg aat aat ggc tac tcc tac atg tct ggt 672 Asn Ile Ala Ser Thr Val Pro Asn Asn Gly Tyr Ser Tyr Met Ser Gly 210 215 220 acg tcc atg gca tcc cct cac gtg gcc ggt ttg gct gct ttg ttg gca 720 Thr Ser Met Ala Ser Pro His Val Ala Gly Leu Ala Ala Leu Leu Ala 225 230 235 240 agt caa ggt aag aat aac gta caa atc cgc cag gcc att gag caa acc 768 Ser Gln Gly Lys Asn Asn Val Gln Ile Arg Gln Ala Ile Glu Gln Thr 245 250 255 gcc gat aag atc tct ggc act gga aca aac ttc aag tat ggt aaa atc 816 Ala Asp Lys Ile Ser Gly Thr Gly Thr Asn Phe Lys Tyr Gly Lys Ile 260 265 270 aac tca aac aaa gct gta aga tac 840 Asn Ser Asn Lys Ala Val Arg Tyr 275 280 <210> SEQ ID NO 2 <211> LENGTH: 280 <212> TYPE: PRT <213> ORGANISM: bacillus sp. <400> SEQUENCE: 2 Trp Ser Pro Asn Asp Pro Tyr Tyr Ser Ala Tyr Gln Tyr Gly Pro Gln 1 5 10 15 Asn Thr Ser Thr Pro Ala Ala Trp Asp Val Thr Arg Gly Ser Ser Thr 20 25 30 Gln Thr Val Ala Val Leu Asp Ser Gly Val Asp Tyr Asn His Pro Asp 35 40 45 Leu Ala Arg Lys Val Ile Lys Gly Tyr Asp Phe Ile Asp Arg Asp Asn 50 55 60 Asn Pro Met Asp Leu Asn Gly His Gly Thr His Val Ala Gly Thr Val 65 70 75 80 Ala Ala Asp Thr Asn Asn Gly Ile Gly Val Ala Gly Met Ala Pro Asp 85 90 95 Thr Lys Ile Leu Ala Val Arg Val Leu Asp Ala Asn Gly Ser Gly Ser 100 105 110 Leu Asp Ser Ile Ala Ser Gly Ile Arg Tyr Ala Ala Asp Gln Gly Ala 115 120 125 Lys Val Leu Asn Leu Ser Leu Gly Cys Glu Cys Asn Ser Thr Thr Leu 130 135 140 Lys Ser Ala Val Asp Tyr Ala Trp Asn Lys Gly Ala Val Val Val Ala 145 150 155 160 Ala Ala Gly Asn Asp Asn Val Ser Arg Thr Phe Gln Pro Ala Ser Tyr 165 170 175 Pro Asn Ala Ile Ala Val Gly Ala Ile Asp Ser Asn Asp Arg Lys Ala 180 185 190 Ser Phe Ser Asn Tyr Gly Thr Trp Val Asp Val Thr Ala Pro Gly Val 195 200 205 Asn Ile Ala Ser Thr Val Pro Asn Asn Gly Tyr Ser Tyr Met Ser Gly 210 215 220 Thr Ser Met Ala Ser Pro His Val Ala Gly Leu Ala Ala Leu Leu Ala 225 230 235 240 Ser Gln Gly Lys Asn Asn Val Gln Ile Arg Gln Ala Ile Glu Gln Thr 245 250 255 Ala Asp Lys Ile Ser Gly Thr Gly Thr Asn Phe Lys Tyr Gly Lys Ile 260 265 270 Asn Ser Asn Lys Ala Val Arg Tyr 275 280 <210> SEQ ID NO 3 <211> LENGTH: 269 <212> TYPE: PRT <213> ORGANISM: Bacillus lentus <400> SEQUENCE: 3 Ala Gln Ser Val Pro Trp Gly Ile Ser Arg Val Gln Ala Pro Ala Ala 1 5 10 15 His Asn Arg Gly Leu Thr Gly Ser Gly Val Lys Val Ala Val Leu Asp 20 25 30 Thr Gly Ile Ser Thr His Pro Asp Leu Asn Ile Arg Gly Gly Ala Ser 35 40 45 Phe Val Pro Gly Glu Pro Ser Thr Gln Asp Gly Asn Gly His Gly Thr 50 55 60 His Val Ala Gly Thr Ile Ala Ala Leu Asn Asn Ser Ile Gly Val Leu 65 70 75 80 Gly Val Ala Pro Ser Ala Glu Leu Tyr Ala Val Lys Val Leu Gly Ala 85 90 95 Ser Gly Ser Gly Ser Val Ser Ser Ile Ala Gln Gly Leu Glu Trp Ala 100 105 110 Gly Asn Asn Gly Met His Val Ala Asn Leu Ser Leu Gly Ser Pro Ser 115 120 125 Pro Ser Ala Thr Leu Glu Gln Ala Val Asn Ser Ala Thr Ser Arg Gly 130 135 140 Val Leu Val Val Ala Ala Ser Gly Asn Ser Gly Ala Gly Ser Ile Ser 145 150 155 160 Tyr Pro Ala Arg Tyr Ala Asn Ala Met Ala Val Gly Ala Thr Asp Gln 165 170 175 Asn Asn Asn Arg Ala Ser Phe Ser Gln Tyr Gly Ala Gly Leu Asp Ile 180 185 190 Val Ala Pro Gly Val Asn Val Gln Ser Thr Tyr Pro Gly Ser Thr Tyr 195 200 205 Ala Ser Leu Asn Gly Thr Ser Met Ala Thr Pro His Val Ala Gly Ala 210 215 220 Ala Ala Leu Val Lys Gln Lys Asn Pro Ser Trp Ser Asn Val Gln Ile 225 230 235 240 Arg Asn His Leu Lys Asn Thr Ala Thr Ser Leu Gly Ser Thr Asn Leu 245 250 255 Tyr Gly Ser Gly Leu Val Asn Ala Glu Ala Ala Thr Arg 260 265 <210> SEQ ID NO 4 <211> LENGTH: 344 <212> TYPE: PRT <213> ORGANISM: Arthromyces ramosus <400> SEQUENCE: 4 Gln Gly Pro Gly Gly Gly Gly Gly Ser Val Thr Cys Pro Gly Gly Gln 1 5 10 15 Ser Thr Ser Asn Ser Gln Cys Cys Val Trp Phe Asp Val Leu Asp Asp 20 25 30 Leu Gln Thr Asn Phe Tyr Gln Gly Ser Lys Cys Glu Ser Pro Val Arg 35 40 45 Lys Ile Leu Arg Ile Val Phe His Asp Ala Ile Gly Phe Ser Pro Ala 50 55 60 Leu Thr Ala Ala Gly Gln Phe Gly Gly Gly Gly Ala Asp Gly Ser Ile 65 70 75 80 Ile Ala His Ser Asn Ile Glu Leu Ala Phe Pro Ala Asn Gly Gly Leu 85 90 95 Thr Asp Thr Ile Glu Ala Leu Arg Ala Val Gly Ile Asn His Gly Val 100 105 110 Ser Phe Gly Asp Leu Ile Gln Phe Ala Thr Ala Val Gly Met Ser Asn 115 120 125 Cys Pro Gly Ser Pro Arg Leu Glu Phe Leu Thr Gly Arg Ser Asn Ser 130 135 140 Ser Gln Pro Ser Pro Pro Ser Leu Ile Pro Gly Pro Gly Asn Thr Val 145 150 155 160 Thr Ala Ile Leu Asp Arg Met Gly Asp Ala Gly Phe Ser Pro Asp Glu 165 170 175 Val Val Asp Leu Leu Ala Ala His Ser Leu Ala Ser Gln Glu Gly Leu 180 185 190 Asn Ser Ala Ile Phe Arg Ser Pro Leu Asp Ser Thr Pro Gln Val Phe 195 200 205 Asp Thr Gln Phe Tyr Ile Glu Thr Leu Leu Lys Gly Thr Thr Gln Pro 210 215 220 Gly Pro Ser Leu Gly Phe Ala Glu Glu Leu Ser Pro Phe Pro Gly Glu 225 230 235 240 Phe Arg Met Arg Ser Asp Ala Leu Leu Ala Arg Asp Ser Arg Thr Ala 245 250 255 Cys Arg Trp Gln Ser Met Thr Ser Ser Asn Glu Val Met Gly Gln Arg 260 265 270 Tyr Arg Ala Ala Met Ala Lys Met Ser Val Leu Gly Phe Asp Arg Asn 275 280 285 Ala Leu Thr Asp Cys Ser Asp Val Ile Pro Ser Ala Val Ser Asn Asn 290 295 300 Ala Ala Pro Val Ile Pro Gly Gly Leu Thr Val Asp Asp Ile Glu Val 305 310 315 320 Ser Cys Pro Ser Glu Pro Phe Pro Glu Ile Ala Thr Ala Ser Gly Pro 325 330 335 Leu Pro Ser Leu Ala Pro Ala Pro 340 <210> SEQ ID NO 5 <211> LENGTH: 876 <212> TYPE: DNA <213> ORGANISM: Humicola lanuginosa DSM 4109 <220> FEATURE: <221> NAME/KEY: CDS <222> LOCATION: (1)...(876) <221> NAME/KEY: sig_peptide <222> LOCATION: (1)...(66) <221> NAME/KEY: mat_peptide <222> LOCATION: (67)...(876) <400> SEQUENCE: 5 atg agg agc tcc ctt gtg ctg ttc ttt gtc tct gcg tgg acg gcc ttg 48 Met Arg Ser Ser Leu Val Leu Phe Phe Val Ser Ala Trp Thr Ala Leu -20 -15 -10 gcc agt cct att cgt cga gag gtc tcg cag gat ctg ttt aac cag ttc 96 Ala Ser Pro Ile Arg Arg Glu Val Ser Gln Asp Leu Phe Asn Gln Phe -5 1 5 10 aat ctc ttt gca cag tat tct gca gcc gca tac tgc gga aaa aac aat 144 Asn Leu Phe Ala Gln Tyr Ser Ala Ala Ala Tyr Cys Gly Lys Asn Asn 15 20 25 gat gcc cca gct ggt aca aac att acg tgc acg gga aat gcc tgc ccc 192 Asp Ala Pro Ala Gly Thr Asn Ile Thr Cys Thr Gly Asn Ala Cys Pro 30 35 40 gag gta gag aag gcg gat gca acg ttt ctc tac tcg ttt gaa gac tct 240 Glu Val Glu Lys Ala Asp Ala Thr Phe Leu Tyr Ser Phe Glu Asp Ser 45 50 55 gga gtg ggc gat gtc acc ggc ttc ctt gct ctc gac aac acg aac aaa 288 Gly Val Gly Asp Val Thr Gly Phe Leu Ala Leu Asp Asn Thr Asn Lys 60 65 70 ttg atc gtc ctc tct ttc cgt ggc tct cgt tcc ata gag aac tgg atc 336 Leu Ile Val Leu Ser Phe Arg Gly Ser Arg Ser Ile Glu Asn Trp Ile 75 80 85 90 ggg aat ctt aac ttc gac ttg aaa gaa ata aat gac att tgc tcc ggc 384 Gly Asn Leu Asn Phe Asp Leu Lys Glu Ile Asn Asp Ile Cys Ser Gly 95 100 105 tgc agg gga cat gac ggc ttc act tcg tcc tgg agg tct gta gcc gat 432 Cys Arg Gly His Asp Gly Phe Thr Ser Ser Trp Arg Ser Val Ala Asp 110 115 120 acg tta agg cag aag gtg gag gat gct gtg agg gag cat ccc gac tat 480 Thr Leu Arg Gln Lys Val Glu Asp Ala Val Arg Glu His Pro Asp Tyr 125 130 135 cgc gtg gtg ttt acc gga cat agc ttg ggt ggt gca ttg gca act gtt 528 Arg Val Val Phe Thr Gly His Ser Leu Gly Gly Ala Leu Ala Thr Val 140 145 150 gcc gga gca gac ctg cgt gga aat ggg tat gat atc gac gtg ttt tca 576 Ala Gly Ala Asp Leu Arg Gly Asn Gly Tyr Asp Ile Asp Val Phe Ser 155 160 165 170 tat ggc gcc ccc cga gtc gga aac agg gct ttt gca gaa ttc ctg acc 624 Tyr Gly Ala Pro Arg Val Gly Asn Arg Ala Phe Ala Glu Phe Leu Thr 175 180 185 gta cag acc ggc gga aca ctc tac cgc att acc cac acc aat gat att 672 Val Gln Thr Gly Gly Thr Leu Tyr Arg Ile Thr His Thr Asn Asp Ile 190 195 200 gtc cct aga ctc ccg ccg cgc gaa ttc ggt tac agc cat tct agc cca 720 Val Pro Arg Leu Pro Pro Arg Glu Phe Gly Tyr Ser His Ser Ser Pro 205 210 215 gag tac tgg atc aaa tct gga acc ctt gtc ccc gtc acc cga aac gat 768 Glu Tyr Trp Ile Lys Ser Gly Thr Leu Val Pro Val Thr Arg Asn Asp 220 225 230 atc gtg aag ata gaa ggc atc gat gcc acc ggc ggc aat aac cag cct 816 Ile Val Lys Ile Glu Gly Ile Asp Ala Thr Gly Gly Asn Asn Gln Pro 235 240 245 250 aac att ccg gat atc cct gcg cac cta tgg tac ttc ggg tta att ggg 864 Asn Ile Pro Asp Ile Pro Ala His Leu Trp Tyr Phe Gly Leu Ile Gly 255 260 265 aca tgt ctt tag 876 Thr Cys Leu * <210> SEQ ID NO 6 <211> LENGTH: 291 <212> TYPE: PRT <213> ORGANISM: Humicola lanuginosa DSM 4109 <220> FEATURE: <221> NAME/KEY: SIGNAL <222> LOCATION: (1)...(22) <400> SEQUENCE: 6 Met Arg Ser Ser Leu Val Leu Phe Phe Val Ser Ala Trp Thr Ala Leu -20 -15 -10 Ala Ser Pro Ile Arg Arg Glu Val Ser Gln Asp Leu Phe Asn Gln Phe -5 1 5 10 Asn Leu Phe Ala Gln Tyr Ser Ala Ala Ala Tyr Cys Gly Lys Asn Asn 15 20 25 Asp Ala Pro Ala Gly Thr Asn Ile Thr Cys Thr Gly Asn Ala Cys Pro 30 35 40 Glu Val Glu Lys Ala Asp Ala Thr Phe Leu Tyr Ser Phe Glu Asp Ser 45 50 55 Gly Val Gly Asp Val Thr Gly Phe Leu Ala Leu Asp Asn Thr Asn Lys 60 65 70 Leu Ile Val Leu Ser Phe Arg Gly Ser Arg Ser Ile Glu Asn Trp Ile 75 80 85 90 Gly Asn Leu Asn Phe Asp Leu Lys Glu Ile Asn Asp Ile Cys Ser Gly 95 100 105 Cys Arg Gly His Asp Gly Phe Thr Ser Ser Trp Arg Ser Val Ala Asp 110 115 120 Thr Leu Arg Gln Lys Val Glu Asp Ala Val Arg Glu His Pro Asp Tyr 125 130 135 Arg Val Val Phe Thr Gly His Ser Leu Gly Gly Ala Leu Ala Thr Val 140 145 150 Ala Gly Ala Asp Leu Arg Gly Asn Gly Tyr Asp Ile Asp Val Phe Ser 155 160 165 170 Tyr Gly Ala Pro Arg Val Gly Asn Arg Ala Phe Ala Glu Phe Leu Thr 175 180 185 Val Gln Thr Gly Gly Thr Leu Tyr Arg Ile Thr His Thr Asn Asp Ile 190 195 200 Val Pro Arg Leu Pro Pro Arg Glu Phe Gly Tyr Ser His Ser Ser Pro 205 210 215 Glu Tyr Trp Ile Lys Ser Gly Thr Leu Val Pro Val Thr Arg Asn Asp 220 225 230 Ile Val Lys Ile Glu Gly Ile Asp Ala Thr Gly Gly Asn Asn Gln Pro 235 240 245 250 Asn Ile Pro Asp Ile Pro Ala His Leu Trp Tyr Phe Gly Leu Ile Gly 255 260 265 Thr Cys Leu <210> SEQ ID NO 7 <211> LENGTH: 32 <212> TYPE: DNA <213> ORGANISM: R28K oligo <400> SEQUENCE: 7 gggatgtaac caagggaagc agcactcaaa cg 32 <210> SEQ ID NO 8 <211> LENGTH: 27 <212> TYPE: DNA <213> ORGANISM: R169K oligo <400> SEQUENCE: 8 cgactttatc gataaggaca ataaccc 27 <210> SEQ ID NO 9 <211> LENGTH: 27 <212> TYPE: DNA <213> ORGANISM: R169K oligo <400> SEQUENCE: 9 caatgtatcc aaaacgttcc aaccagc 27 

What is claimed is:
 1. A conjugate comprising a protease moiety conjugated to one or more polymers, wherein the protease moiety is a Bacillus lentus protease comprising one or more of the following substitutions: P5K, R10K, R19K, H39K, P40K, L42K, L75K, N76K, L82K, P86K, S103K, V104K, S105K, A108K, A133K, T134K, L135K, R145K, R170K, R186K, Q206K, G211K, S212K, A215K, S216K, R247K and N269K, wherein the positions are numbered according to the amino acid sequence of the mature subtilisin BPN′.
 2. The conjugate of claim 1, wherein the protease has an amino acid sequence of SEQ ID NO:
 3. 3. The conjugate of claim 1, wherein the polymer(s) have a molecular weight from 1 to 60 kDa.
 4. The conjugate of claim 1, wherein the polymer(s) are natural or synthetic homo- or heteropolymers.
 5. The conjugate of claim 1, wherein the polymer(s) are selected from the group consisting of polyols, polyamines, polycarboxyl acids and polymers comprising a hydroxyl group and an amine group.
 6. The conjugate of claim 1, wherein the polymer(s) are selected from the group consisting of polyalkylene oxides (PAO), PEG-glycidyl ethers (Epox-PEG), PEG-oxycarbonylimidazole (CDI-PEG), branched PEGs, poly-vinyl alcohols (PVA), poly-carboxylates, polyvinylpyrolidones, poly-D,L-amino acids, polyethylene-co-maleic acid anhydride, polystyrene-co-malic acid anhydrides, dextrans, heparins, homologous albumins, celluloses, hydrolysates of chitosan, starches, glycogen, agaroses and derivatives thereof, guar gum, pullulan, inulin, xanthan gum, carrageenin, pectin, alginic acid hydrolysates and bio-polymers.
 7. The conjugate of claim 1, wherein the polymer(s) are polyalkylene glycols (PAG) or methoxypolyethylene glycols (mPEG).
 8. The conjugate of claim 1, wherein the polymer(s) are selected from the group consisting of polyethylene glycols (PEG), polypropylene glycols and carboxymethyl-dextrans.
 9. The conjugate of claim 1, wherein the polymer(s) are selected from the group consisting of methylcellulose, carboxymethylcellulose, ethylcellulose, hydroxyethylcellulose carboxyethylcellulose and hydroxypropylcellulose.
 10. The conjugate of claim 1, wherein the polymer(s) are hydroxyethyl-starches or hydroxypropyl-starches.
 11. The conjugate of claim 1, wherein the polymer(s) are methoxypolyethylene glycols (mPEG). 